Difference between revisions of "Complexity Zoo References"

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PDQP/qpoly = ALL,
 
PDQP/qpoly = ALL,
 
arXiv:[https://arxiv.org/abs/1805.08577 1805.08577].
 
arXiv:[https://arxiv.org/abs/1805.08577 1805.08577].
 +
 +
<span id="aboe08" style="color:maroon">[ABOE08]</span>
 +
D. Aharonov, M. Ben-Or, E. Eban.
 +
Interactive Proofs for Quantum Computations,
 +
arXiv:[https://arxiv.org/abs/0810.5375 0810.5375].
  
 
<span id="ak06" style="color:maroon">[AK06]</span>
 
<span id="ak06" style="color:maroon">[AK06]</span>
Line 332: Line 337:
 
<i>ACM Transactions on Algorithms (TALG)</i> 2(2): 153–177, 2006.
 
<i>ACM Transactions on Algorithms (TALG)</i> 2(2): 153–177, 2006.
 
[http://dx.doi.org/10.1145/1150334.1150336 doi:10.1145/1150334.1150336]
 
[http://dx.doi.org/10.1145/1150334.1150336 doi:10.1145/1150334.1150336]
 +
 +
<span id="ani+23" style="color:maroon">[Ani+23]</span>
 +
Joshua Ani et al.
 +
Complexity of Motion Planning of Arbitrarily Many Robots: Gadgets, Petri Nets, and Counter Machines. 2023.
 +
arxiv: [https://arxiv.org/abs/2306.01193]
  
 
<span id="an02" style="color:maroon">[AN02]</span>
 
<span id="an02" style="color:maroon">[AN02]</span>
Line 501: Line 511:
 
<i>Journal of Computer and System Sciences</i> 44(2):193-219, 1992.
 
<i>Journal of Computer and System Sciences</i> 44(2):193-219, 1992.
 
[http://www.cs.technion.ac.il/~shai/aver.pdf http://www.cs.technion.ac.il/~shai/aver.pdf]
 
[http://www.cs.technion.ac.il/~shai/aver.pdf http://www.cs.technion.ac.il/~shai/aver.pdf]
 +
 +
<span id="bckls14" style="color:maroon">[BCK+14]</span>
 +
H. Buhrman, R. Cleve, M. Koucky, B. Loff, and F. Speelman.
 +
Computing with a full memory: catalytic space,
 +
<i>Symposium on the Theory of Computing (STOC)</i> 857-866, 2014.
  
 
<span id="bcs97" style="color:maroon">[BCS+97]</span>
 
<span id="bcs97" style="color:maroon">[BCS+97]</span>
Line 861: Line 876:
 
  |link=http://math.ucsd.edu/~sbuss/ResearchWeb/Boolean3/index.html
 
  |link=http://math.ucsd.edu/~sbuss/ResearchWeb/Boolean3/index.html
 
}}
 
}}
 +
 +
<span id="buss17" style="color:maroon">[Buss17]</span>
 +
S. Buss.
 +
Uniform Proofs of ACC Representations,
 +
<i>Archive for Mathematical Logic</i> 56(5–6):639–669, 2017.
  
 
<span id="bv97" style="color:maroon">[BV97]</span>
 
<span id="bv97" style="color:maroon">[BV97]</span>
Line 901: Line 921:
 
Lecture Notes in Computer Science, vol 247, p148-158, 1987.
 
Lecture Notes in Computer Science, vol 247, p148-158, 1987.
  
<span id="can96" style="color:maroon">[Can96]</span>
+
<span id="cch01" style="color:maroon">[CCH+01]</span>
R. Canetti.
+
J.-Y. Cai, V. Chakaravarthy, L. Hemaspaandra, and M. Ogihara.
More on BPP and the polynomial-time hierarchy,
+
Some Karp-Lipton-type theorems based on S<sub>2</sub>,
<i>Information Processing Letters</i> 57:237-241, 1996.
+
University of Rochester Computer Science Technical Report TR-759, November 2001.
  
 
<span id="cc93" style="color:maroon">[CC93]</span>
 
<span id="cc93" style="color:maroon">[CC93]</span>
Line 916: Line 936:
 
<i>Journal of Computer and System Sciences</i> 54(3):465-474, 1997.
 
<i>Journal of Computer and System Sciences</i> 54(3):465-474, 1997.
  
<span id="cs12" style="color:maroon">[CS12]</span>
+
<span id="cf91" style="color:maroon">[CF91]</span>
André Chailloux and Or Sattath.
+
J.-Y. Cai and M. Furst.
The Complexity of the Separable Hamiltonian Problem,
+
PSPACE survives constant-width bottlenecks,
<i>Proceedings of the 2012 IEEE Annual Conference on Computational Complexity (CCC)</i>, pp. 32-41, 2012. [https://arxiv.org/abs/1111.5247 arXiv: 1111.5247].
+
<i>International Journal of Foundations of Computer Science</i> 2(1):67-76, 1991.
 +
 
 +
<span id="co22" style="color:maroon">[CO22]</span>
 +
Wojciech Czerwiński and Łukasz Orlikowski
 +
Reachability in vector addition systems is Ackermann-complete,
 +
<i>Proceedings of the 62nd Annual IEEE Symposium on Foundations of Computer Science</i>, pages 1229–1240, 2022
 +
arXiv: [https://arxiv.org/abs/2104.13866]
  
<span id="ccd03" style="color:maroon">[CCD+03]</span>
+
<span id="can96" style="color:maroon">[Can96]</span>
A. M. Childs, R. Cleve, E. Deotto, E. Farhi, S. Gutmann, and D. A. Spielman.
+
R. Canetti.
Exponential algorithmic speedup by quantum walk,
+
More on BPP and the polynomial-time hierarchy,
<i>Proceedings of ACM Symposium on Theory of Computing</i>, pp. 59-68, 2003.
+
<i>Information Processing Letters</i> 57:237-241, 1996.
arXiv:[http://arxiv.org/abs/quant-ph/0209131 quant-ph/0209131].
 
  
 
<span id="ccg94" style="color:maroon">[CCG+94]</span>
 
<span id="ccg94" style="color:maroon">[CCG+94]</span>
Line 932: Line 957:
 
<i>Journal of Computer and System Sciences</i> 49(1):24-39, 1994.
 
<i>Journal of Computer and System Sciences</i> 49(1):24-39, 1994.
  
<span id="cch01" style="color:maroon">[CCH+01]</span>
+
<span id="cgqtz24" style="color:maroon">[CGQ+24]</span>
J.-Y. Cai, V. Chakaravarthy, L. Hemaspaandra, and M. Ogihara.
+
Z. Chen, J. A. Grochow, Y. Qiao, G. Tang, and C. Zhang.
Some Karp-Lipton-type theorems based on S<sub>2</sub>,
+
On the complexity of isomorphism problems for tensors, groups, and polynomials III: actions by classical groups.
University of Rochester Computer Science Technical Report TR-759, November 2001.
+
<i>Proc. ITCS '24</i> [https://doi.org/10.4230/LIPIcs.ITCS.2024.31 doi:10.4230/LIPIcs.ITCS.2024.31]
  
<span id="cd05" style="color:maroon">[CD05]</span>
+
<span id="cs12" style="color:maroon">[CS12]</span>
X. Chen and X. Deng
+
André Chailloux and Or Sattath.
3-NASH is PPAD-Complete,
+
The Complexity of the Separable Hamiltonian Problem,
ECCC [http://eccc.uni-trier.de/eccc-reports/2005/TR05-134/ TR05-134].
+
<i>Proceedings of the 2012 IEEE Annual Conference on Computational Complexity (CCC)</i>, pp. 32-41, 2012. [https://arxiv.org/abs/1111.5247 arXiv: 1111.5247].
 +
 
 +
<span id="ctw13" style="color:maroon">[CTW13]</span>
 +
A. Chattopadhyay, J. Tor&aacute;n, F. Wagner.
 +
Graph Isomorphism is Not AC0-Reducible to Group Isomorphism
 +
<i>ACM Transactions on Computation Theory</i> Volume 5, Issue 4, November 2013, pp.1--13. [https://doi.org/10.1145/2540088]
 +
 
 +
<span id="cw22" style="color:maroon">[CW22]</span>
 +
B. Chapman and R. Williams.
 +
Smaller ACC0 Circuits for Symmetric Functions,
 +
<i>13th Innovations in Theoretical Computer Science Conference (ITCS 2022)</i>, pp. 38:1--38:19, 2022. [https://arxiv.org/abs/2107.04706  arXiv:2107.04706], [https://drops.dagstuhl.de/opus/volltexte/2022/15634  LIPIcs-ITCS-2022-38].
  
 
<span id="che16" style="color:maroon">[Che16]</span>
 
<span id="che16" style="color:maroon">[Che16]</span>
Line 946: Line 981:
 
A Note on Oracle Separations for BQP,
 
A Note on Oracle Separations for BQP,
 
arXiv:[http://arxiv.org/abs/1605.00619 1605.00619].
 
arXiv:[http://arxiv.org/abs/1605.00619 1605.00619].
 +
 +
<span id="cd05" style="color:maroon">[CD05]</span>
 +
X. Chen and X. Deng
 +
3-NASH is PPAD-Complete,
 +
ECCC [http://eccc.uni-trier.de/eccc-reports/2005/TR05-134/ TR05-134].
 +
 +
<span id="ccd03" style="color:maroon">[CCD+03]</span>
 +
A. M. Childs, R. Cleve, E. Deotto, E. Farhi, S. Gutmann, and D. A. Spielman.
 +
Exponential algorithmic speedup by quantum walk,
 +
<i>Proceedings of ACM Symposium on Theory of Computing</i>, pp. 59-68, 2003.
 +
arXiv:[http://arxiv.org/abs/quant-ph/0209131 quant-ph/0209131].
  
 
<span id="cdl01" style="color:maroon">[CDL01]</span>
 
<span id="cdl01" style="color:maroon">[CDL01]</span>
Line 951: Line 997:
 
Division in logspace-uniform NC<sub>1</sub>,
 
Division in logspace-uniform NC<sub>1</sub>,
 
<i>Theoretical Informatics and Applications</i> 35(3):259, 2001.
 
<i>Theoretical Informatics and Applications</i> 35(3):259, 2001.
 
<span id="cf91" style="color:maroon">[CF91]</span>
 
J.-Y. Cai and M. Furst.
 
PSPACE survives constant-width bottlenecks,
 
<i>International Journal of Foundations of Computer Science</i> 2(1):67-76, 1991.
 
  
 
{{Reference
 
{{Reference
Line 1,037: Line 1,078:
 
On pseudorandom generators in NC<sup>0</sup>,
 
On pseudorandom generators in NC<sup>0</sup>,
 
<i>Proceedings of the 26th International Symposium on Mathematical Foundations of Computer Science (MFCS)</i>, pp. 272-284, 2001.
 
<i>Proceedings of the 26th International Symposium on Mathematical Foundations of Computer Science (MFCS)</i>, pp. 272-284, 2001.
 +
 +
<span id="cm16" style="color:maroon">[CM16]</span>
 +
T. Cubitt and A. Montanaro.
 +
Complexity Classification of Local Hamiltonian Problems.
 +
<i>SIAM Journal on Computing</i> 45:2, 2016.
 +
doi:[https://epubs.siam.org/doi/abs/10.1137/140998287 10.1137/140998287].
 +
 +
<span id="cmp18" style="color:maroon">[CMP18]</span>
 +
T. Cubitt, A. Montanaro, and S. Piddock.
 +
Universal quantum Hamiltonians.
 +
<i>PNAS</i> 115:38, 2018.
 +
doi:[https://www.pnas.org/doi/full/10.1073/pnas.1804949115 10.1073/pnas.1804949115].
  
 
{{Reference
 
{{Reference
Line 1,162: Line 1,215:
 
<span id="dam90" style="color:maroon">[Dam90]</span>
 
<span id="dam90" style="color:maroon">[Dam90]</span>
 
C. Damm.
 
C. Damm.
Problems complete for L,
+
Problems complete for ⊕L,
 
<i>Information Processing Letters</i> 36:247-250, 1990.
 
<i>Information Processing Letters</i> 36:247-250, 1990.
 +
[https://doi.org/10.1016/0020-0190(90)90150-V doi:10.1016/0020-0190(90)90150-V]
  
 
<span id="dam91" style="color:maroon">[Dam91]</span>
 
<span id="dam91" style="color:maroon">[Dam91]</span>
Line 1,174: Line 1,228:
 
Complexity theory of parallel time and hardware,
 
Complexity theory of parallel time and hardware,
 
<i>Information and Computation</i> 80:205-226, 1989.
 
<i>Information and Computation</i> 80:205-226, 1989.
 +
[https://doi.org/10.1016/0890-5401(89)90009-6 doi:10.1016/0890-5401(89)90009-6]
  
 
<span id="ddp98" style="color:maroon">[DDP+98]</span>
 
<span id="ddp98" style="color:maroon">[DDP+98]</span>
Line 1,179: Line 1,234:
 
Image density is complete for non-interactive SZK,
 
Image density is complete for non-interactive SZK,
 
<i>Proceedings of the 25th International Colloquium on Automata, Languages, and Programming (ICALP)</i>, Lecture Notes in Computer Science, pp. 784-795, 1998.
 
<i>Proceedings of the 25th International Colloquium on Automata, Languages, and Programming (ICALP)</i>, Lecture Notes in Computer Science, pp. 784-795, 1998.
 +
[https://doi.org/10.1007/BFb0055102 doi:10.1007/BFb0055102]
 
(Note: Some results in the paper were later retracted.)
 
(Note: Some results in the paper were later retracted.)
  
Line 1,184: Line 1,240:
 
M. I. Dekhtyar.
 
M. I. Dekhtyar.
 
On the relativization of deterministic and nondeterministic complexity classes,
 
On the relativization of deterministic and nondeterministic complexity classes,
<i>Mathematical Foundations of Computer Science</i>, pp. 255-259, Springer LNCS 45, 1976.
+
<i>Mathematical Foundations of Computer Science</i> (MFCS '76), pp. 255-259, Springer LNCS 45, 1976.
 +
[https://doi.org/10.1007/3-540-07854-1_183 doi:10.1007/3-540-07854-1_183]
  
 
<span id="dgpv20" style="color:maroon">[DGPV20]</span>
 
<span id="dgpv20" style="color:maroon">[DGPV20]</span>
 
P. Dixon, S. Gayen, A. Pavan, N. V. Vinodchandran.
 
P. Dixon, S. Gayen, A. Pavan, N. V. Vinodchandran.
 
Perfect Zero Knowledge: New Upperbounds and Relativized Separations,
 
Perfect Zero Knowledge: New Upperbounds and Relativized Separations,
<i>Theory of Cryptography Conference</i>, pp. 768, 2020.
+
<i>Theory of Cryptography Conference</i> (TCC '20), pp. 768, 2020.
 
ePrint:[https://eprint.iacr.org/2020/768]
 
ePrint:[https://eprint.iacr.org/2020/768]
 +
[https://doi.org/10.1007/978-3-030-64375-1_24 doi:10.1007/978-3-030-64375-1_24]
  
 
<span id="df97" style="color:maroon">[DF97]</span>
 
<span id="df97" style="color:maroon">[DF97]</span>
Line 1,196: Line 1,254:
 
Threshold dominating sets and an improved characterization of W[2],
 
Threshold dominating sets and an improved characterization of W[2],
 
<i>Theoretical Computer Science</i> 189, 1997.
 
<i>Theoretical Computer Science</i> 189, 1997.
 +
[https://doi.org/10.1016/S0304-3975(97)00101-1 doi:10.1016/S0304-3975(97)00101-1]
  
 
<span id="df99" style="color:maroon">[DF99]</span>
 
<span id="df99" style="color:maroon">[DF99]</span>
Line 1,201: Line 1,260:
 
<i>Parameterized Complexity</i>,
 
<i>Parameterized Complexity</i>,
 
Springer-Verlag Monographs in Computer Science, 1999.
 
Springer-Verlag Monographs in Computer Science, 1999.
 +
[https://doi.org/10.1007/978-1-4612-0515-9 doi:10.1007/978-1-4612-0515-9]
  
 
<span id="dft96" style="color:maroon">[DFT96]</span>
 
<span id="dft96" style="color:maroon">[DFT96]</span>
Line 1,206: Line 1,266:
 
On the parameteric complexity of relational database queries and a sharper characterization of W[1],
 
On the parameteric complexity of relational database queries and a sharper characterization of W[1],
 
<i>Combinatorics, Complexity, and Logic</i>, Proceedings of DMTCS'96, Springer-Verlag, pp. 194-213, 1996.
 
<i>Combinatorics, Complexity, and Logic</i>, Proceedings of DMTCS'96, Springer-Verlag, pp. 194-213, 1996.
 +
[http://mrfellows.net/papers/C33-relationaldatabase.ps Author's website version]
  
 
<span id="dft98" style="color:maroon">[DFT96]</span>
 
<span id="dft98" style="color:maroon">[DFT96]</span>
 
R. G. Downey, M. R. Fellows, and U. Taylor.
 
R. G. Downey, M. R. Fellows, and U. Taylor.
Parameterized circuit complexity and the W
+
Parameterized circuit complexity and the W hierarchy.
hierarchy.
 
 
<i>Theoret. Computer Sci.</i>, 191(1–2):97–115, January 1998.
 
<i>Theoret. Computer Sci.</i>, 191(1–2):97–115, January 1998.
 +
[https://doi.org/10.1016/S0304-3975(96)00317-9 doi:10.1016/S0304-3975(96)00317-9]
  
 
<span id="dgp05" style="color:maroon">[DGP05]</span>
 
<span id="dgp05" style="color:maroon">[DGP05]</span>
 
C. Daskalakis, P. W. Goldberg, and C. H. Papadimitriou
 
C. Daskalakis, P. W. Goldberg, and C. H. Papadimitriou
The Complexity of Computing a Nash Equilibrium, online: [http://www.cs.berkeley.edu/~christos/papers/ppad.ps ppad.ps], sep. 2005.
+
The Complexity of Computing a Nash Equilibrium,
 +
<i>SIAM J. Comput.</i> 39(1):195-259, 2009.
 +
[https://doi.org/10.1137/070699652 doi:10.1137/070699652]
 +
Originally appeared in [https://doi.org/10.1145/1132516.1132527 STOC 2006], [https://people.csail.mit.edu/costis/simplified.pdf Author's website conference version].
  
 
<span id="dhi02" style="color:maroon">[DHI02]</span>
 
<span id="dhi02" style="color:maroon">[DHI02]</span>
 
W. van Dam, S. Hallgren, and L. Ip.
 
W. van Dam, S. Hallgren, and L. Ip.
 
Quantum algorithms for hidden shift problems,
 
Quantum algorithms for hidden shift problems,
arXiv:[http://arxiv.org/abs/quant-ph/0211140 quant-ph/0211140], 2002.
+
<i>SIAM J. Comput.</i> 36(3):763-778, 2006.
 +
[https://doi.org/10.1137/S009753970343141X doi:10.1137/S009753970343141X]
 +
Originally appeared on arXiv:[http://arxiv.org/abs/quant-ph/0211140 quant-ph/0211140] and SODA 2003.
  
 
<span id="dp05" style="color:maroon">[DP05]</span>
 
<span id="dp05" style="color:maroon">[DP05]</span>
C. Daskalakis and C. H. Papadimitriou
+
C. Daskalakis and C. H. Papadimitriou.
The Complexity of Computing a Nash Equilibrium, online: [http://www.cs.berkeley.edu/~christos/papers/3players.pdf 3players.pdf], nov. 2005.
+
Three-player games are hard,
 +
ECCC [https://eccc.weizmann.ac.il//eccc-reports/2005/TR05-139/ TR05-139], 2005.
  
{{Reference-ECCC
+
<span id="DP08" style="color:maroon">[DP08]</span>
    |tag=DP08 |year=2008 |date=Feb 28 |eccc-num=TR08-014
+
M. David and T. Pitassi.
    |authors=M. David and T. Pitassi
+
Separating NOF communication complexity classes RP and NP.
    |title=Separating NOF communication complexity classes RP and NP
+
ECCC [https://eccc.weizmann.ac.il/eccc-reports/2008/TR08-014/index.html TR08-014] and arXiv:[https://doi.org/10.48550/arXiv.0802.3860 0802.3860 [cs.CC]], 2008.
}}
 
  
 
<span id="dw86" style="color:maroon">[DW86]</span>
 
<span id="dw86" style="color:maroon">[DW86]</span>
Line 1,236: Line 1,302:
 
Membership for growing context-sensitive grammars is polynomial,
 
Membership for growing context-sensitive grammars is polynomial,
 
<i>Journal of Computer and System Sciences</i> 33:456-472, 1986.
 
<i>Journal of Computer and System Sciences</i> 33:456-472, 1986.
 +
[https://doi.org/10.1016/0022-0000(86)90062-0 doi:10.1016/0022-0000(86)90062-0]
 +
Originally appeared in [https://doi.org/10.1007/BFb0022661 CAAP 1986]
  
 
===== E =====
 
===== E =====
Line 1,243: Line 1,311:
 
Paths, trees, and flowers,
 
Paths, trees, and flowers,
 
<i>Canadian Journal of Mathematics</i> 17(3):449-467, 1965.
 
<i>Canadian Journal of Mathematics</i> 17(3):449-467, 1965.
 +
[https://doi.org/10.4153/CJM-1965-045-4 doi:10.4153/CJM-1965-045-4]
  
 
<span id="ey07" style="color:maroon">[EY07]</span>
 
<span id="ey07" style="color:maroon">[EY07]</span>
 
K. Etessami and M. Yannakakis.
 
K. Etessami and M. Yannakakis.
 
On the Complexity of Nash Equilibria and Other Fixed Points.
 
On the Complexity of Nash Equilibria and Other Fixed Points.
Proceedings IEEE FOCS '07. SIAM J. Comput. 2010. doi:10.1137/080720826
+
<i>SIAM J. Comput.</i> 2010.  
 +
[https://doi.org/10.1137/080720826 doi:10.1137/080720826]
 +
Originally appeared in [https://doi.org/10.1109/FOCS.2007.39 FOCS 2007].
 +
[https://homepages.inf.ed.ac.uk/kousha/nash_focs07_full_j_spec_issue_sub.pdf Author's website version]
  
 
===== F =====
 
===== F =====
Line 1,253: Line 1,325:
 
<span id="fag73" style="color:maroon">[Fag73]</span>
 
<span id="fag73" style="color:maroon">[Fag73]</span>
 
R. Fagin.
 
R. Fagin.
Contributions to the Model Theory of Finite Strucutres,
+
Contributions to the Model Theory of Finite Structures,
 
<i>Ph.D. Thesis (1973), U.C. Berkeley</i>
 
<i>Ph.D. Thesis (1973), U.C. Berkeley</i>
  
Line 1,260: Line 1,332:
 
Generalized first-order spectra and polynomial-time recognizable sets,
 
Generalized first-order spectra and polynomial-time recognizable sets,
 
<i>Complexity of Computation</i> (R. M. Karp, ed.), SIAM-AMS Proceedings Vol. 7, 1974.
 
<i>Complexity of Computation</i> (R. M. Karp, ed.), SIAM-AMS Proceedings Vol. 7, 1974.
 +
[https://www.researchgate.net/publication/242608657_Generalized_first-order_spectra_and_polynomial_time_recognizable_sets Author's uploaded copy]
  
 
<span id="fen02" style="color:maroon">[Fen02]</span>
 
<span id="fen02" style="color:maroon">[Fen02]</span>
Line 1,265: Line 1,338:
 
PP-lowness and a simple definition of AWPP,
 
PP-lowness and a simple definition of AWPP,
 
<i>Theory Comput. Syst.</i> 36 (2003), no. 2, 199--212.
 
<i>Theory Comput. Syst.</i> 36 (2003), no. 2, 199--212.
 +
[https://doi.org/10.1007/s00224-002-1089-8 doi:10.1007/s00224-002-1089-8]
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2002/TR02-036/ TR02-036].
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2002/TR02-036/ TR02-036].
  
Line 1,274: Line 1,348:
 
S. Fenner, L. Fortnow, S. Kurtz, and L. Li.
 
S. Fenner, L. Fortnow, S. Kurtz, and L. Li.
 
An oracle builder's toolkit,
 
An oracle builder's toolkit,
<i>Proceedings of Structure in Complexity Theory</i>, pages 120-131, 1993.
+
<i>Inform. Comput.</i> 182(2):95-136, 2003.
[http://people.cs.uchicago.edu/~fortnow/papers/obt.ps http://people.cs.uchicago.edu/~fortnow/papers/obt.ps].
+
[https://doi.org/10.1016/S0890-5401(03)00018-X doi:10.1016/S0890-5401(03)00018-X]
 +
Originally appeared in [https://doi.org/10.1109/SCT.1993.336534 <i>Structure in Complexity Theory</i>, pages 120-131, 1993].
 +
[https://lance.fortnow.com/papers/files/obt.pdf Author's website version].
  
 
<span id="ffk94" style="color:maroon">[FFK94]</span>
 
<span id="ffk94" style="color:maroon">[FFK94]</span>
Line 1,281: Line 1,357:
 
Gap-definable counting classes,
 
Gap-definable counting classes,
 
<i>Journal of Computer and System Sciences</i> 48(1):116-148, 1994.
 
<i>Journal of Computer and System Sciences</i> 48(1):116-148, 1994.
[http://people.cs.uchicago.edu/~fortnow/papers/gaps.ps http://people.cs.uchicago.edu/~fortnow/papers/gaps.ps].
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[https://doi.org/10.1016/S0022-0000(05)80024-8 doi:10.1016/S0022-0000(05)80024-8].
 +
Originally appeared in [https://doi.org/10.1109/SCT.1991.160241 <i>Structure in Complexity Theory</i>, 1991].
 +
[https://lance.fortnow.com/papers/files/gaps.pdf Author's website version].
  
 
<span id="fg02" style="color:maroon">[FG02]</span>
 
<span id="fg02" style="color:maroon">[FG02]</span>
 
J. Flum and M. Grohe.
 
J. Flum and M. Grohe.
 
The parameterized complexity of counting problems,
 
The parameterized complexity of counting problems,
<i>Proceedings of IEEE FOCS'2002</i>, 2002.
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<i>SIAM J. Comput.</i> 33(4):892-922, 2004. [https://doi.org/10.1137/S0097539703427203 doi:10.1137/S0097539703427203]
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Originally appeared in [https://doi.org/10.1109/SFCS.2002.1181978 FOCS '02].
  
 
<span id="fgh98" style="color:maroon">[FGH+98]</span>
 
<span id="fgh98" style="color:maroon">[FGH+98]</span>
Line 1,298: Line 1,377:
 
Approximating clique is almost NP-complete,
 
Approximating clique is almost NP-complete,
 
<i>Proceedings of IEEE FOCS'91</i>, pp. 2-12, 1991.
 
<i>Proceedings of IEEE FOCS'91</i>, pp. 2-12, 1991.
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[https://doi.org/10.1109/SFCS.1991.185341 doi:10.1109/SFCS.1991.185341]
  
 
<span id="fgmsz89" style="color:maroon">[FGM+89]</span>
 
<span id="fgmsz89" style="color:maroon">[FGM+89]</span>
Line 1,316: Line 1,396:
 
NP with small advice,
 
NP with small advice,
 
<i>Proceedings of IEEE Complexity'2005</i>, pp. 228-234, 2005.
 
<i>Proceedings of IEEE Complexity'2005</i>, pp. 228-234, 2005.
[http://people.cs.uchicago.edu/~fortnow/papers/fk.ps http://people.cs.uchicago.edu/~fortnow/papers/fk.ps].
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[https://doi.org/10.1109/CCC.2005.15 doi:10.1109/CCC.2005.15]
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[https://lance.fortnow.com/papers/files/fk.pdf Author's website version].
  
 
<span id="fk97" style="color:maroon">[FK97]</span>
 
<span id="fk97" style="color:maroon">[FK97]</span>
Line 1,322: Line 1,403:
 
Limited versus polynomial nondeterminism,
 
Limited versus polynomial nondeterminism,
 
<i>Chicago Journal of Theoretical Computer Science</i> Article 1, 1997.
 
<i>Chicago Journal of Theoretical Computer Science</i> Article 1, 1997.
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[http://dx.doi.org/10.4086/cjtcs.1997.001 doi:10.4086/cjtcs.1997.001]
  
 
<span id="fk97b" style="color:maroon">[FK97b]</span>
 
<span id="fk97b" style="color:maroon">[FK97b]</span>
Line 1,327: Line 1,409:
 
Making games short,
 
Making games short,
 
<i>Proceedings of ACM STOC'1997</i>, pp. 506-516, 1997.
 
<i>Proceedings of ACM STOC'1997</i>, pp. 506-516, 1997.
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[https://doi.org/10.1145/258533.258644 doi:10.1145/258533.258644]
  
 
<span id="fmf16" style="color:maroon">[FMF16]</span>
 
<span id="fmf16" style="color:maroon">[FMF16]</span>
Line 1,332: Line 1,415:
 
Hierarchical complexity of 2-clique-colouring weakly chordal graphs and perfect graphs having cliques of size at least 3,
 
Hierarchical complexity of 2-clique-colouring weakly chordal graphs and perfect graphs having cliques of size at least 3,
 
<i>Theoretical Computer Science</i> 618, 2016.
 
<i>Theoretical Computer Science</i> 618, 2016.
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[https://doi.org/10.1016/j.tcs.2016.01.027 doi:10.1016/j.tcs.2016.01.027]
 
arXiv:[https://arxiv.org/abs/1312.2086 cs.CC/1312.2086].
 
arXiv:[https://arxiv.org/abs/1312.2086 cs.CC/1312.2086].
  
Line 1,338: Line 1,422:
 
The role of relativization in complexity theory,
 
The role of relativization in complexity theory,
 
<i>Bulletin of the EATCS</i> 52, February 1994.
 
<i>Bulletin of the EATCS</i> 52, February 1994.
[http://people.cs.uchicago.edu/~fortnow/papers/relative.ps http://people.cs.uchicago.edu/~fortnow/papers/relative.ps].
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[https://lance.fortnow.com/papers/files/relative.pdf Author's website version].
  
 
<span id="for02" style="color:maroon">[For02]</span>
 
<span id="for02" style="color:maroon">[For02]</span>
Line 1,344: Line 1,428:
 
A linear lower bound on the unbounded error probabilistic communication complexity,
 
A linear lower bound on the unbounded error probabilistic communication complexity,
 
<i>Journal of Computer and System Sciences</i> 65(4):612-625, 2002.
 
<i>Journal of Computer and System Sciences</i> 65(4):612-625, 2002.
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[https://doi.org/10.1016/S0022-0000(02)00019-3 doi:10.1016/S0022-0000(02)00019-3]
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Originally appeared in [https://doi.org/10.1109/CCC.2001.933877 CCC '01]
  
 
<span id="fr74" style="color:maroon">[FR74]</span>
 
<span id="fr74" style="color:maroon">[FR74]</span>
Line 1,349: Line 1,435:
 
Super-exponential complexity of Presburger arithmetic,
 
Super-exponential complexity of Presburger arithmetic,
 
<i>Complexity of Computation</i> (R. M. Karp, ed.), SIAM-AMS Symposium on Applied Mathematics, 1974.
 
<i>Complexity of Computation</i> (R. M. Karp, ed.), SIAM-AMS Symposium on Applied Mathematics, 1974.
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Reprinted in 1998 at [https://doi.org/10.1007/978-3-7091-9459-1_5 doi:10.1007/978-3-7091-9459-1_5].
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Preliminary version [https://dspace.mit.edu/bitstream/handle/1721.1/148872/MIT-LCS-TM-043.pdf?sequence=1 MIT Project MAC Tech Report].
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<span id="fr96" style="color:maroon">[FR96]</span>
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L. Fortnow and N. Reingold.
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PP is closed under truth-table reductions,
 +
<i>Information and Computation</i> 124(1):1–6, 1996.
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[http://doi.org/10.1006/inco.1996.0001 doi:10.1006/inco.1996.0001]
  
 
<span id="fr98" style="color:maroon">[FR98]</span>
 
<span id="fr98" style="color:maroon">[FR98]</span>
 
L. Fortnow and J. D. Rogers.
 
L. Fortnow and J. D. Rogers.
 
Complexity limitations on quantum computation,
 
Complexity limitations on quantum computation,
<i>Proceedings of IEEE Complexity'98</i>, pp. 202-209, 1998.
+
<i>J. Comput. Syst. Sci.</i> 59(2): 240–252. 1999. Special issue for selected papers from the 13th IEEE Conference on Computational Complexity.
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Originally appeared in CCC '98.
 
arXiv:[http://arxiv.org/abs/cs.CC/9811023 cs.CC/9811023].
 
arXiv:[http://arxiv.org/abs/cs.CC/9811023 cs.CC/9811023].
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<span id="fr21" style="color:maroon">[FR21]</span>
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B. Fefferman and Z. Remscrim.
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Eliminating intermediate measurements in space-bounded Quantum computation,
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<i>Proceedings of ACM STOC'2021</i>, pp. 1343–1356, 2021.
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arXiv:[http://arxiv.org/abs/2006.03530 cs.CC/2006.03530].
  
 
<span id="fri57" style="color:maroon">[Fri57]</span>
 
<span id="fri57" style="color:maroon">[Fri57]</span>
Line 1,360: Line 1,462:
 
Two recursively enumerable sets of incomparable degrees of unsolvability,
 
Two recursively enumerable sets of incomparable degrees of unsolvability,
 
<i>Proceedings of the National Academy of Sciences</i>, 43:236-238, 1957.
 
<i>Proceedings of the National Academy of Sciences</i>, 43:236-238, 1957.
[http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=528418&amp;blobtype=pdf http://www.pubmedcentral.nih.gov/picrender.fcgi?artid=528418&amp;blobtype=pdf].
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[https://doi.org/10.1073/pnas.43.2.236 doi:10.1073/pnas.43.2.236].
  
 
<span id="frs88" style="color:maroon">[FRS88]</span>
 
<span id="frs88" style="color:maroon">[FRS88]</span>
 
L. Fortnow, J. Rompel, and M. Sipser.
 
L. Fortnow, J. Rompel, and M. Sipser.
 
On the power of multiprover interactive protocols,
 
On the power of multiprover interactive protocols,
<i>Proceedings of IEEE Complexity'88</i>, 1988.
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<i>Theoret. Comput. Sci.</i> 134(2):545-557, 1994.
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[https://doi.org/10.1016/0304-3975(94)90251-8 doi:10.1016/0304-3975(94)90251-8]
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Originally appeared in [https://doi.org/10.1109/SCT.1988.5275 Complexity '88]
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[https://lance.fortnow.com/papers/files/mip.pdf Author's website version].
  
 
<span id="fs04" style="color:maroon">[FS04]</span>
 
<span id="fs04" style="color:maroon">[FS04]</span>
Line 1,372: Line 1,476:
 
Hierarchy theorems for probabilistic polynomial time,
 
Hierarchy theorems for probabilistic polynomial time,
 
<i>Proceedings of IEEE FOCS'2004</i>, 2004.
 
<i>Proceedings of IEEE FOCS'2004</i>, 2004.
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[https://lance.fortnow.com/papers/files/probhier.pdf Author's website version]
  
 
<span id="fs88" style="color:maroon">[FS88]</span>
 
<span id="fs88" style="color:maroon">[FS88]</span>
Line 1,378: Line 1,483:
 
Are there interactive protocols for co-NP languages?
 
Are there interactive protocols for co-NP languages?
 
Inform. Process. Lett. 28 (1988), no. 5, 249--251.
 
Inform. Process. Lett. 28 (1988), no. 5, 249--251.
[http://cs-www.uchicago.edu/~fortnow/papers/conpipl.ps http://cs-www.uchicago.edu/~fortnow/papers/conpipl.ps]
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[http://doi.org/10.1016/0020-0190(88)90199-8 doi:10.1016/0020-0190(88)90199-8]
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[https://lance.fortnow.com/papers/files/conpipl.pdf Author's website version]
  
 
<span id="fss84" style="color:maroon">[FSS84]</span>
 
<span id="fss84" style="color:maroon">[FSS84]</span>
Line 1,384: Line 1,490:
 
Parity, circuits, and the polynomial hierarchy,
 
Parity, circuits, and the polynomial hierarchy,
 
<i>Mathematical Systems Theory</i> 17:13-27, 1984.
 
<i>Mathematical Systems Theory</i> 17:13-27, 1984.
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[https://doi.org/10.1007/BF01744431 doi:10.1007/BF01744431]
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Originally appeared in [https://doi.org/10.1109/SFCS.1981.35 FOCS '81].
  
 
<span id="fsw09" style="color:maroon">[FSW09]</span>
 
<span id="fsw09" style="color:maroon">[FSW09]</span>
Line 1,389: Line 1,497:
 
Fixed-Polynomial Size Circuit Bounds,
 
Fixed-Polynomial Size Circuit Bounds,
 
<i>Poceedings of the 24th Annual IEEE Conference on Computational Complexity</i>, pp. 19-26, 2009.
 
<i>Poceedings of the 24th Annual IEEE Conference on Computational Complexity</i>, pp. 19-26, 2009.
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[https://doi.org/10.1109/CCC.2009.21 doi:CCC.2009.21]
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[https://people.csail.mit.edu/rrw/circuit.pdf Author's website version].
  
 
<span id="fur07" style="color:maroon">[Fur07]</span>
 
<span id="fur07" style="color:maroon">[Fur07]</span>
 
M. Furer.
 
M. Furer.
Fast Integer Multiplication,
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Faster Integer Multiplication,
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<i>Proc. ACM STOC 2007</i>, pp. 57-66.
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<span id="fv93" style="color:maroon">[FV93]</span>
 
<span id="fv93" style="color:maroon">[FV93]</span>
Line 1,455: Line 1,565:
 
Extended abstract appeared in <i>Proceeedings of the 39th International Colloquium on Automata, Languages, and Programming (ICALP)</i>, pages 387-398, Springer, 2012.
 
Extended abstract appeared in <i>Proceeedings of the 39th International Colloquium on Automata, Languages, and Programming (ICALP)</i>, pages 387-398, Springer, 2012.
  
<span id="gsssy18" style="color:maroon">[GSSSY18]</span>
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<span id="gkm15" style="color:maroon">[GKM15]</span>
S. Gharibian, M. Santha, J. Sikora, A. Sundaram, and J. Yirka.
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V. Girard, M. Koucky, and P. McKenzie.
Quantum Generalizations of the Polynomial Hierarchy with Applications to QMA(2),
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Nonuniform catalytic space and the direct sum for space,
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ECCC [https://eccc.weizmann.ac.il/report/2015/138/]
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<span id="gkr15" style="color:maroon">[GKR15]</span>
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S. Goldwasser, Y. Kalai, and G. Rothblum.
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Delegating Computation: Interactive Proofs for Muggles,
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<i>Journal of the ACM</i> 62(4), 2015
  
 
<span id="gkr95" style="color:maroon">[GKR+95]</span>
 
<span id="gkr95" style="color:maroon">[GKR+95]</span>
Line 1,480: Line 1,595:
 
Rectangles Are Nonnegative Juntas,
 
Rectangles Are Nonnegative Juntas,
 
<i>Proceedings of ACM STOC'15</i>, pp. 257-266, 2015.
 
<i>Proceedings of ACM STOC'15</i>, pp. 257-266, 2015.
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<span id="glv24" style="color:maroon">[GLV24]</span>
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K. Gajulapalli, Z. Li, I. Volkovich
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Oblivious Classes Revisited: Lower Bounds and Hierarchies,
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ECCC [https://eccc.weizmann.ac.il/report/2024/049/]
  
 
<span id="gm15" style="color:maroon">[GM15]</span>
 
<span id="gm15" style="color:maroon">[GM15]</span>
Line 1,553: Line 1,673:
 
<span id="gq19" style="color:maroon">[GQ19]</span>
 
<span id="gq19" style="color:maroon">[GQ19]</span>
 
J. A. Grochow and Y. Qiao.
 
J. A. Grochow and Y. Qiao.
Isomorphism problems for tensors, groups, and cubic forms: completeness and reductions,
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On the Complexity of Isomorphism Problems for Tensors, Groups, and Polynomials I: Tensor Isomorphism-Completeness,
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<i>SIAM J. Comput.</i> 52(2):568-617, 2023 [https://doi.org/10.1137/21M1441110 doi:10.1137/21M1441110].
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<span id="gq21" style="color:maroon">[GQ21]</span>
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J. A. Grochow and Y. Qiao.
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On p-Group Isomorphism: search-to-decision, counting-to-decision, and nilpotency class reductions via tensors,
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<i>ACM Trans. Comput. Theory</i> 16(1):2:1-2:39. [https://doi.org/10.1145/3625308 doi:10.1145/3625308].
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Originally appeared in [https://doi.org/10.4230/LIPIcs.CCC.2021.16 CCC '21].
  
 
<span id="gra92" style="color:maroon">[Grä92]</span>
 
<span id="gra92" style="color:maroon">[Grä92]</span>
Line 1,622: Line 1,749:
 
Disjoint NP-pairs,
 
Disjoint NP-pairs,
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2003/TR03-011/ TR03-011], 2003.
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2003/TR03-011/ TR03-011], 2003.
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<span id="gsssy18" style="color:maroon">[GSSSY18]</span>
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S. Gharibian, M. Santha, J. Sikora, A. Sundaram, and J. Yirka.
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Quantum Generalizations of the Polynomial Hierarchy with Applications to QMA(2),
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<i>Computational Complexity</i> 31, 13, 2022.
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<span id="gst03" style="color:maroon">[GST03]</span>
 
<span id="gst03" style="color:maroon">[GST03]</span>
Line 1,705: Line 1,838:
 
<span id="gy16" style="color:maroon">[GY16]</span>
 
<span id="gy16" style="color:maroon">[GY16]</span>
 
S. Gharibian, and J. Yirka.
 
S. Gharibian, and J. Yirka.
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The complexity of simulating local measurements on quantum systems,
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<span id="gy24" style="color:maroon">[GY24]</span>
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S. Grewal, and J. Yirka.
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The Entangled Quantum Polynomial Hierarchy Collapses,  
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arXiv:[https://arxiv.org/abs/2401.01453 quant-ph/2401.01453], 2024.
  
 
<span id="gz97" style="color:maroon">[GZ97]</span>
 
<span id="gz97" style="color:maroon">[GZ97]</span>
Line 1,712: Line 1,851:
 
Another proof that BPP subseteq PH (and more),
 
Another proof that BPP subseteq PH (and more),
 
ECCC [http://eccc.uni-trier.de/eccc-reports/1997/TR97-045/ TR97-045].
 
ECCC [http://eccc.uni-trier.de/eccc-reports/1997/TR97-045/ TR97-045].
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<span id="ghj22" style="color:maroon">[GHJ+22]</span>
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M. Göös, A. Hollender, S. Jain, G. Maystre, W. Pires, R. Robere, R. Tao
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===== H =====
 
===== H =====
Line 1,918: Line 2,063:
 
Oracles for structural properties: the isomorphism problem and public-key cryptography,
 
Oracles for structural properties: the isomorphism problem and public-key cryptography,
 
<i>Journal of Computer and System Sciences</i> 44(2):287-301, 1992.
 
<i>Journal of Computer and System Sciences</i> 44(2):287-301, 1992.
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<span id="hs05" style="color:maroon">[HS05]</span>
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P. Høyer and R. Špalek.
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Qauntum fan-out is powerful,
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<i>Theory of computing</i> (1)1:81-103, 2005.
  
 
<span id="ht03" style="color:maroon">[HT03]</span>
 
<span id="ht03" style="color:maroon">[HT03]</span>
Line 1,942: Line 2,092:
 
A note concerning nondeterministic tape complexities,
 
A note concerning nondeterministic tape complexities,
 
<i>Journal of the ACM</i> 4:608-612, 1972.
 
<i>Journal of the ACM</i> 4:608-612, 1972.
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<span id="ikw01" style="color:maroon">[IKW01]</span>
 
<span id="ikw01" style="color:maroon">[IKW01]</span>
 
R. Impagliazzo, V. Kabanets, and A. Wigderson.
 
R. Impagliazzo, V. Kabanets, and A. Wigderson.
 
In search of an easy witness: exponential time vs. probabilistic polynomial time,
 
In search of an easy witness: exponential time vs. probabilistic polynomial time,
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<i>J. Comput. Syst. Sci.</i>, 2002.
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<span id="il90" style="color:maroon">[IL90]</span>
 
<span id="il90" style="color:maroon">[IL90]</span>
Line 1,953: Line 2,106:
 
No better ways to generate hard NP instances than picking uniformly at random,
 
No better ways to generate hard NP instances than picking uniformly at random,
 
<i>Proceedings of IEEE FOCS'90</i>, pp. 812-821, 1990.
 
<i>Proceedings of IEEE FOCS'90</i>, pp. 812-821, 1990.
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[https://doi.org/10.1109/FSCS.1990.89604 doi:10.1109/FSCS.1990.89604]
  
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R. Impagliazzo.
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A personal view of average-case complexity,
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<i>Proceedings of the 10th Conference on Structure in Complexity Theory</i>, 134-147, 1995.
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<span id="imm82" style="color:maroon">[Imm82]</span>
 
<span id="imm82" style="color:maroon">[Imm82]</span>
 
N. Immerman.
 
N. Immerman.
 
Relational queries computable in in polynomial time.
 
Relational queries computable in in polynomial time.
<i>14th ACM STOC Symp. (1987), 86-104</i>
+
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<span id="mvw99" style="color:maroon">[MVW99]</span>
Line 2,632: Line 2,892:
 
Super-polynomial versus half-exponential circuit size in the exponential hierarchy,
 
Super-polynomial versus half-exponential circuit size in the exponential hierarchy,
 
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Line 2,650: Line 2,912:
 
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Ordered quantum branching programs are more powerful than ordered probabilistic branching programs under a bounded-width restriction,
 
Ordered quantum branching programs are more powerful than ordered probabilistic branching programs under a bounded-width restriction,
 
<i>Proceedings of COCOON'2000 (Computing and Combinatorics)</i>, Springer LNCS 1858, pp. 467-476, 2000.
 
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<span id="nie02" style="color:maroon">[Nie02]</span>
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The Growing Context-Sensitive Languages Are the Acyclic Context-Sensitive Languages,
 
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N. Nisan.
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<i>Theoretical Computer Science</i> 194:137-161, 1998.
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Average-case computations - comparing AvgP, HP, and Nearly-P,
 
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Undirected connectivity in O(log<sup>1.5</sup>n) space,
 
Undirected connectivity in O(log<sup>1.5</sup>n) space,
 
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H. Nishimura and T. Yamakami.
 
H. Nishimura and T. Yamakami.
 
Polynomial time quantum computation with advice,
 
Polynomial time quantum computation with advice,
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<i>Inform. Proc. Lett.</i>, 90(4):195-204, 2004.
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[https://doi.org/10.1016/j.ipl.2004.02.005 doi:10.1016/j.ipl.2004.02.005]
 
arXiv:[http://arxiv.org/abs/quant-ph/0305100 quant-ph/0305100],
 
arXiv:[http://arxiv.org/abs/quant-ph/0305100 quant-ph/0305100],
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2003/TR03-059/ TR03-059], 2003.
 
ECCC [http://eccc.uni-trier.de/eccc-reports/2003/TR03-059/ TR03-059], 2003.
Line 2,718: Line 3,004:
 
H. Nishimura and T. Yamakami.
 
H. Nishimura and T. Yamakami.
 
An algorithmic argument for query complexity lower bounds of advised quantum computation,
 
An algorithmic argument for query complexity lower bounds of advised quantum computation,
arXiv:[http://arxiv.org/abs/quant-ph/0312003 quant-ph/0312003], 2003.
+
<i>MFCS</i>, pp. 827–838, 2004.
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[https://doi.org/10.1007/978-3-540-28629-5_65 doi:10.1007/978-3-540-28629-5_65]
 +
arXiv:[http://arxiv.org/abs/quant-ph/0312003 quant-ph/0312003]
  
 
===== O =====
 
===== O =====
Line 2,726: Line 3,014:
 
On serializable languages,
 
On serializable languages,
 
<i>International Journal of Foundations of Computer Science</i> 5(3-4):303-318, 1994.
 
<i>International Journal of Foundations of Computer Science</i> 5(3-4):303-318, 1994.
 +
[https://doi.org/10.1142/S0129054194000177 doi:10.1142/S0129054194000177]
  
 
<span id="oh93" style="color:maroon">[OH93]</span>
 
<span id="oh93" style="color:maroon">[OH93]</span>
Line 2,731: Line 3,020:
 
A complexity theory for feasible closure properties,
 
A complexity theory for feasible closure properties,
 
<i>Journal of Computer and System Sciences</i> 46(3):295-325, 1993.
 
<i>Journal of Computer and System Sciences</i> 46(3):295-325, 1993.
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[https://doi.org/10.1016/0022-0000(93)90006-I doi:10.1016/0022-0000(93)90006-I]
  
 
<span id="oka96" style="color:maroon">[Oka96]</span>
 
<span id="oka96" style="color:maroon">[Oka96]</span>
 
T. Okamoto.
 
T. Okamoto.
 
On relationships between statistical zero-knowledge proofs,
 
On relationships between statistical zero-knowledge proofs,
<i>Proceedings of ACM STOC'96</i>, 1996.
+
<i>Journal of Computer and System Sciences</i> 60(1):47-108, 2000.
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[https://doi.org/10.1006/jcss.1999.1664 doi:10.1006/jcss.1999.1664]
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<span id="oks94" style="color:maroon">[OKS+94]</span>
 
<span id="oks94" style="color:maroon">[OKS+94]</span>
Line 2,741: Line 3,033:
 
Instance complexity,
 
Instance complexity,
 
<i>Journal of the ACM</i> 41:96-121, 1994.
 
<i>Journal of the ACM</i> 41:96-121, 1994.
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[https://doi.org/10.1145/174644.174648 doi:10.1145/174644.174648]
  
 
<span id="ost91" style="color:maroon">[Ost91]</span>
 
<span id="ost91" style="color:maroon">[Ost91]</span>
Line 2,746: Line 3,039:
 
One-way functions, hard on average problems and statistical zero-knowledge proofs,
 
One-way functions, hard on average problems and statistical zero-knowledge proofs,
 
<i>Proceedings of IEEE Complexity'91</i>, pp. 51-59, 1991.
 
<i>Proceedings of IEEE Complexity'91</i>, pp. 51-59, 1991.
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[https://doi.org/10.1109/SCT.1991.160253 doi:10.1109/SCT.1991.160253]
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[https://web.cs.ucla.edu/~rafail/PUBLIC/06.pdf Author's website version]
  
 
<span id="ow93" style="color:maroon">[OW93]</span>
 
<span id="ow93" style="color:maroon">[OW93]</span>
Line 2,751: Line 3,046:
 
One-way functions are essential for non-trivial zero-knowledge,
 
One-way functions are essential for non-trivial zero-knowledge,
 
<i>Proceedings of the 2nd Israel Symposium on Theory of Computing and Systems (ISTCS-93)</i>, 1993.
 
<i>Proceedings of the 2nd Israel Symposium on Theory of Computing and Systems (ISTCS-93)</i>, 1993.
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[https://doi.org/10.1109/ISTCS.1993.253489 doi:10.1109/ISTCS.1993.253489]
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[https://web.cs.ucla.edu/~rafail/PUBLIC/14.pdf Author's website version]
  
 
===== P =====
 
===== P =====
Line 2,757: Line 3,054:
 
C. H. Papadimitriou.
 
C. H. Papadimitriou.
 
Games against nature,
 
Games against nature,
<i>Proceedings of IEEE FOCS'83</i>, pp. 446-450, 1983.
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<i>J. Comput. Syst. Sci.</i> 31(2):288-301, 1985.
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[https://doi.org/10.1016/0022-0000(85)90045-5 doi:10.1016/0022-0000(85)90045-5]
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<span id="pap90" style="color:maroon">[Pap90]</span>
 
<span id="pap90" style="color:maroon">[Pap90]</span>
Line 2,763: Line 3,062:
 
On graph-theoretic lemmata and complexity classes,
 
On graph-theoretic lemmata and complexity classes,
 
<i>Proceedings of IEEE FOCS'90</i>, pp. 794-801, 1990.
 
<i>Proceedings of IEEE FOCS'90</i>, pp. 794-801, 1990.
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<span id="pap94" style="color:maroon">[Pap94]</span>
 
<span id="pap94" style="color:maroon">[Pap94]</span>
Line 2,773: Line 3,073:
 
On the complexity of the parity argument and other inefficient proofs of existence,
 
On the complexity of the parity argument and other inefficient proofs of existence,
 
<i>Journal of Computer and System Sciences</i> 48(3):498-532, 1994.
 
<i>Journal of Computer and System Sciences</i> 48(3):498-532, 1994.
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{{Reference
 
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     |srcdetail=347-357, 2007
 
     |srcdetail=347-357, 2007
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}}
 
}}
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<span id="pm15" style="color:maroon">[PM15]</span>
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S. Piddock and A. Montanaro.
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The complexity of antiferromagnetic interactions and 2D lattices.
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arXiv:[https://arxiv.org/abs/1506.04014 1506.04014], 2015.
  
 
<span id="pos44" style="color:maroon">[Pos44]</span>
 
<span id="pos44" style="color:maroon">[Pos44]</span>
Line 2,786: Line 3,093:
 
Recursively enumerable sets of positive integers and their decision problems,
 
Recursively enumerable sets of positive integers and their decision problems,
 
<i>Bulletin of the American Mathematical Society</i> 50:284-316, 1944.
 
<i>Bulletin of the American Mathematical Society</i> 50:284-316, 1944.
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[https://doi.org/10.1090/S0002-9904-1944-08111-1 doi:10.1090/S0002-9904-1944-08111-1]
  
 
<span id="pp00" style="color:maroon">[PP00]</span>
 
<span id="pp00" style="color:maroon">[PP00]</span>
Line 2,791: Line 3,099:
 
Efficient factorization with a single pure qubit and log N mixed qubits,
 
Efficient factorization with a single pure qubit and log N mixed qubits,
 
<i>Physical Review Letters</i> 85:3049, 2000.
 
<i>Physical Review Letters</i> 85:3049, 2000.
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arXiv:[http://arxiv.org/abs/quant-ph/0001066 quant-ph/0001066].
 
arXiv:[http://arxiv.org/abs/quant-ph/0001066 quant-ph/0001066].
  
Line 2,797: Line 3,106:
 
On determinism versus nondeterminism and related problems,
 
On determinism versus nondeterminism and related problems,
 
<i>Proceedings of IEEE FOCS'83</i>, pp. 429-438, 1983.
 
<i>Proceedings of IEEE FOCS'83</i>, pp. 429-438, 1983.
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[https://doi.org/10.1109/SFCS.1983.39 doi:10.1109/SFCS.1983.39]
  
 
<span id="pps14" style="color:maroon">[PPS14]</span>
 
<span id="pps14" style="color:maroon">[PPS14]</span>
Line 2,802: Line 3,112:
 
Overlays and limited memory communication,
 
Overlays and limited memory communication,
 
<i>Proceedings of IEEE CCC'14</i>, pp. 298-308, 2014.
 
<i>Proceedings of IEEE CCC'14</i>, pp. 298-308, 2014.
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<span id="pra74" style="color:maroon">[Pra74]</span>
 
<span id="pra74" style="color:maroon">[Pra74]</span>
 
V. R. Pratt.
 
V. R. Pratt.
 
The power of negative thinking in multiplying Boolean matrices,
 
The power of negative thinking in multiplying Boolean matrices,
<i>STOC '74: Proceedings of the sixth annual ACM Symposium on Theory of Computing</i>, 80-83, 1974.
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<span id="pra75" style="color:maroon">[Pra75]</span>
 
<span id="pra75" style="color:maroon">[Pra75]</span>
Line 2,812: Line 3,124:
 
Every prime has a succinct certificate,
 
Every prime has a succinct certificate,
 
<i>SIAM Journal on Computing</i>, 4:214-220, 1975.
 
<i>SIAM Journal on Computing</i>, 4:214-220, 1975.
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<span id="ps86" style="color:maroon">[PS86]</span>
 
<span id="ps86" style="color:maroon">[PS86]</span>
Line 2,817: Line 3,130:
 
Probabilistic communication complexity,
 
Probabilistic communication complexity,
 
<i>Journal of Computer and System Sciences</i>, 33(1):106-123, 1986.
 
<i>Journal of Computer and System Sciences</i>, 33(1):106-123, 1986.
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<span id="pv04" style="color:maroon">[PV04]</span>
 
<span id="pv04" style="color:maroon">[PV04]</span>
 
A. Pavan and N. V. Vinodchandran.
 
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Polylogarithmic Round Arthur-Merlin Games and Random-Self-Reducibility
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<span id="py84" style="color:maroon">[PY84]</span>
 
<span id="py84" style="color:maroon">[PY84]</span>
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The complexity of facets (and some facets of complexity),
 
The complexity of facets (and some facets of complexity),
 
<i>Journal of Computer and System Sciences</i> 28:244-259, 1984.
 
<i>Journal of Computer and System Sciences</i> 28:244-259, 1984.
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<span id="py88" style="color:maroon">[PY88]</span>
 
<span id="py88" style="color:maroon">[PY88]</span>
 
C. H. Papadimitriou and M. Yannakakis.
 
C. H. Papadimitriou and M. Yannakakis.
 
Optimization, approximation, and complexity classes,
 
Optimization, approximation, and complexity classes,
<i>Proceedings of ACM STOC'88</i>, pp. 229-234, 1988.
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<i>J. Comput. Syst. Sci.</i> 43(3): 425-440 (1991)
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<span id="py96" style="color:maroon">[PY96]</span>
 
<span id="py96" style="color:maroon">[PY96]</span>
Line 2,836: Line 3,155:
 
On limited nondeterminism and the complexity of the VC dimension,
 
On limited nondeterminism and the complexity of the VC dimension,
 
<i>Journal of Computer and System Sciences</i> 53(2):161-170, 1996.
 
<i>Journal of Computer and System Sciences</i> 53(2):161-170, 1996.
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<span id="pz83" style="color:maroon">[PZ83]</span>
 
<span id="pz83" style="color:maroon">[PZ83]</span>
Line 2,841: Line 3,161:
 
Two remarks on the power of counting,
 
Two remarks on the power of counting,
 
<i>Proceedings of the 6th GI Conference in Theoretical Computer Science</i>, Lecture Notes in Computer Science Vol. 145, Springer-Verlag, pp. 269-276, 1983.
 
<i>Proceedings of the 6th GI Conference in Theoretical Computer Science</i>, Lecture Notes in Computer Science Vol. 145, Springer-Verlag, pp. 269-276, 1983.
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===== R =====
 
===== R =====
Line 2,850: Line 3,171:
 
ECCC [http://eccc.uni-trier.de/eccc-reports/1997/TR97-014/ TR97-014],
 
ECCC [http://eccc.uni-trier.de/eccc-reports/1997/TR97-014/ TR97-014],
 
DIMACS [http://dimacs.rutgers.edu/TechnicalReports/abstracts/1997/97-46.html TR 97-46].
 
DIMACS [http://dimacs.rutgers.edu/TechnicalReports/abstracts/1997/97-46.html TR 97-46].
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<span id="rab60" style="color:maroon">[Rab60]</span>
 
<span id="rab60" style="color:maroon">[Rab60]</span>
Line 2,938: Line 3,261:
 
Polylogarithmic-time deterministic network decomposition and distributed derandomization,
 
Polylogarithmic-time deterministic network decomposition and distributed derandomization,
 
<i>Symposium on Theory of Computing (STOC)</i>, 2020.
 
<i>Symposium on Theory of Computing (STOC)</i>, 2020.
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On Threshold Circuits and Polynomial Computation,
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Line 3,058: Line 3,386:
 
Separating nondeterministic time complexity classes,
 
Separating nondeterministic time complexity classes,
 
<i>Journal of the ACM</i> 25:146-167, 1978.
 
<i>Journal of the ACM</i> 25:146-167, 1978.
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<span id="sha10" style="color:maroon">[Sha10]</span>
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M. Schaefer.
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Complexity of some geometric and topological problems,
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<span id="sha90" style="color:maroon">[Sha90]</span>
 
<span id="sha90" style="color:maroon">[Sha90]</span>
Line 3,207: Line 3,540:
  
 
===== T =====
 
===== T =====
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<span id="tak12" style="color:maroon">[Tak12]</span>
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Y. Takahashi. and T. Seiichiro
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Collapse of the hierarchy of constant-depth exact quantum circuits
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<span id="tan07" style="color:maroon">[Tan07]</span>
Line 3,212: Line 3,552:
 
Logspace Optimization Problems and Their Approximability Properties,
 
Logspace Optimization Problems and Their Approximability Properties,
 
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<span id="tar88" style="color:maroon">[Tar88]</span>
 
<span id="tar88" style="color:maroon">[Tar88]</span>
Line 3,217: Line 3,559:
 
The gap between monotone and non-monotone circuit complexity is exponential,
 
The gap between monotone and non-monotone circuit complexity is exponential,
 
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<span id="tar89" style="color:maroon">[Tar89]</span>
 
<span id="tar89" style="color:maroon">[Tar89]</span>
Line 3,222: Line 3,566:
 
Query complexity, or why is it difficult to separate NP<sup>A</sup> intersect coNP<sup>A</sup> from P<sup>A</sup> by random oracles A,
 
Query complexity, or why is it difficult to separate NP<sup>A</sup> intersect coNP<sup>A</sup> from P<sup>A</sup> by random oracles A,
 
<i>Combinatorica</i>, 9:385-392, 1989.
 
<i>Combinatorica</i>, 9:385-392, 1989.
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<span id="tha98" style="color:maroon">[Tha98]</span>
Line 3,231: Line 3,576:
 
<span id="tod89" style="color:maroon">[Tod89]</span>
 
<span id="tod89" style="color:maroon">[Tod89]</span>
 
S. Toda.
 
S. Toda.
On the computational power of PP and P,
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On the computational power of PP and (+)P,
 
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<i>Proceedings of IEEE FOCS'89</i>, pp. 514-519, 1989.
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<span id="tod91" style="color:maroon">[Tod91]</span>
 
<span id="tod91" style="color:maroon">[Tod91]</span>
Line 3,244: Line 3,590:
 
On the hardness of graph isomorphism,
 
On the hardness of graph isomorphism,
 
<i>Proceedings of IEEE FOCS'2000</i>, pp. 180-186, 2000.
 
<i>Proceedings of IEEE FOCS'2000</i>, pp. 180-186, 2000.
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<span id="tor88" style="color:maroon">[Tor88]</span>
 
J. Tor&aacute;n.
 
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Structural Properties of the Counting Hierarchies,
 
Structural Properties of the Counting Hierarchies,
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<span id="tor90" style="color:maroon">[Tor90]</span>
 
<span id="tor90" style="color:maroon">[Tor90]</span>
Line 3,254: Line 3,602:
 
Counting the number of solutions,
 
Counting the number of solutions,
 
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Line 3,259: Line 3,608:
 
Complexity classes defined by counting quantifiers,
 
Complexity classes defined by counting quantifiers,
 
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<span id="tur36" style="color:maroon">[Tur36]</span>
Line 3,264: Line 3,614:
 
On computable numbers, with an application to the <i>Entscheidungsproblem</i>,
 
On computable numbers, with an application to the <i>Entscheidungsproblem</i>,
 
<i>Proceedings of the London Mathematical Society</i> 2(42):230-265, 1936; 2(43):544-546, 1937.
 
<i>Proceedings of the London Mathematical Society</i> 2(42):230-265, 1936; 2(43):544-546, 1937.
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<span id="tv02" style="color:maroon">[TV02]</span>
 
<span id="tv02" style="color:maroon">[TV02]</span>
 
L. Trevisan and S. Vadhan.
 
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===== U =====
 
===== U =====
Line 3,275: Line 3,627:
 
C. Umans.
 
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The minimum equivalent DNF problem and shortest implicants,
 
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===== V =====
 
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Line 3,282: Line 3,635:
 
S. Vadhan.
 
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Three problems in computer science,
 
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Relative complexity of checking and evaluating,
 
Relative complexity of checking and evaluating,
 
<i>Information Processing Letters</i>, 5:20-23, 1976.
 
<i>Information Processing Letters</i>, 5:20-23, 1976.
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The complexity of computing the permanent,
 
The complexity of computing the permanent,
 
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Completeness classes in algebra,
 
Completeness classes in algebra,
 
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Complexity of relational query languages,
 
Complexity of relational query languages,
 
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Properties that characterize LOGCFL,
 
Properties that characterize LOGCFL,
 
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On the power of PP,
 
On the power of PP,
 
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Line 3,323: Line 3,687:
 
Oracle separation of complexity classes and lower bounds for perceptrons solving separation problems,
 
Oracle separation of complexity classes and lower bounds for perceptrons solving separation problems,
 
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<i>Izvestiya Mathematics</i> 59(6):1103-1122, 1995.
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<span id="vin91" style="color:maroon">[Vin91]</span>
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Counting complexity of solvable group problems,
 
Counting complexity of solvable group problems,
 
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<i>SIAM Journal on Computing</i> 33(4):852-869, 2004,
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<span id="vin04b" style="color:maroon">[Vin04b]</span>
 
<span id="vin04b" style="color:maroon">[Vin04b]</span>
 
N. V. Vinodchandran.
 
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A note on the circuit complexity of PP,
 
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Fast parallel computation of polynomials using few processors,
 
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NP is as easy as detecting unique solutions,
 
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===== Y =====
 
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[https://doi.org/10.1109/FSCS.1990.89583 doi:10.1109/FSCS.1990.89583]
  
 
<span id="yao90b" style="color:maroon">[Yao90b]</span>
 
<span id="yao90b" style="color:maroon">[Yao90b]</span>
Line 3,518: Line 3,919:
 
Coherent functions and program checkers,
 
Coherent functions and program checkers,
 
<i>Proceedings of ACM STOC'90</i>, 1990.
 
<i>Proceedings of ACM STOC'90</i>, 1990.
 +
[https://doi.org/10.1145/100216.100226 doi:10.1145/100216.100226]
  
 
<span id="yao93" style="color:maroon">[Yao93]</span>
 
<span id="yao93" style="color:maroon">[Yao93]</span>
Line 3,523: Line 3,925:
 
Quantum circuit complexity,
 
Quantum circuit complexity,
 
<i>Proceedings of IEEE FOCS'93</i>, pp. 352-361, 1993.
 
<i>Proceedings of IEEE FOCS'93</i>, pp. 352-361, 1993.
 +
[https://doi.org/10.1109/SFCS.1993.366852 doi:10.1109/SFCS.1993.366852]
  
 
<span id="yes83" style="color:maroon">[Yes83]</span>
 
<span id="yes83" style="color:maroon">[Yes83]</span>
Line 3,529: Line 3,932:
 
<i>SIAM Journal on Computing</i>, 12(3):411-425, 1983.
 
<i>SIAM Journal on Computing</i>, 12(3):411-425, 1983.
 
DOI:[http://dx.doi.org/10.1137/0212027 10.1137/0212027]
 
DOI:[http://dx.doi.org/10.1137/0212027 10.1137/0212027]
 +
 +
<span id="yir24" style="color:maroon">[Yir24]</span>
 +
J. Yirka.
 +
Even quantum advice is unlikely to solve PP,
 +
arXiv:[https://arxiv.org/abs/2403.09994 2403.09994] [cs.CC],
 +
2024.
  
 
===== Z =====
 
===== Z =====
Line 3,535: Line 3,944:
 
S. Zachos.
 
S. Zachos.
 
Probabilistic quantifiers and games,
 
Probabilistic quantifiers and games,
<i>Journal of Computer and System Sciences</i> 36(3):433-451, 1988.
+
<i>Journal of Computer and System Sciences</i> 36(3):433-451, 1988.  
 +
[https://doi.org/10.1016/0022-0000(88)90037-2 doi:10.1016/0022-0000(88)90037-2]
  
 
<span id="zh86" style="color:maroon">[ZH86]</span>
 
<span id="zh86" style="color:maroon">[ZH86]</span>
 
S. Zachos and H. Heller.
 
S. Zachos and H. Heller.
 
A decisive characterization of BPP.
 
A decisive characterization of BPP.
''Information and Control'', 69(1&ndash;3):125&ndash;135, 1986.
+
''Information and Control'', 69(1&ndash;3):125&ndash;135, 1986.  
 +
[https://doi.org/10.1016/S0019-9958(86)80044-4 doi:10.1016/S0019-9958(86)80044-4]
  
 
<span id="zkt85" style="color:maroon">[ZKT85]</span>
 
<span id="zkt85" style="color:maroon">[ZKT85]</span>
Line 3,552: Line 3,963:
 
Simulating BPP using a general weak random source,
 
Simulating BPP using a general weak random source,
 
<i>Algorithmica</i> 16 (1996), no. 4-5, 367--391
 
<i>Algorithmica</i> 16 (1996), no. 4-5, 367--391
[http://www.cs.utexas.edu/users/diz/pubs/bpp.ps http://www.cs.utexas.edu/users/diz/pubs/bpp.ps].
+
[https://www.cs.utexas.edu/~diz/Sub%20Websites/Research/Simulating_bpp_using_a_general_weak_random_sources.pdf Author's webpage 1995 version].
 
+
[https://doi.org/10.1007/BF01940870 doi:10.1007/BF01940870]
 +
Originally appeared in [https://doi.org/10.1109/SFCS.1991.185351 FOCS 1991]
 
[[Category:Computational Complexity]]
 
[[Category:Computational Complexity]]

Latest revision as of 01:01, 11 November 2024


Main Zoo - Complexity Garden - Zoo Glossary - Zoo References


A - B - C - D - E - F - G - H - I - J - K - L - M - N - O - P - Q - R - S - T - U - V - W - X - Y - Z


A

[Aar02] S. Aaronson. Quantum lower bound for the collision problem, Proceedings of ACM STOC'2002, pp. 635-642, 2002. arXiv:quant-ph/0111102.

[Aar03] S. Aaronson. Lower bounds for local search by quantum arguments, Proceedings of ACM STOC 2004. arXiv:quant-ph/0307149, ECCC TR03-057.

[Aar03b] S. Aaronson. Multilinear formulas and skepticism of quantum computing, Proceedings of ACM STOC 2004. arXiv:quant-ph/0311039, ECCC TR03-079.

[Aar04b] S. Aaronson. Limitations of quantum advice and one-way communication, Proceedings of IEEE Complexity 2004, pp. 320-332, 2004. arXiv:quant-ph/0402095, ECCC TR04-026.

[Aar05] S. Aaronson. Quantum computing and hidden variables, Physical Review A 71:032325, March 2005. arXiv:quant-ph/0408035.

[Aar05b] S. Aaronson. Quantum computing, postselection, and probabilistic polynomial-time, Proceedings of the Royal Society A, 461(2063):3473-3482, 2005. arXiv:quant-ph/0412187.

[Aar05c] S. Aaronson. NP-complete problems and physical reality. ACM SIGACT News, March 2005 quant-ph/0502072.

[Aar06] S. Aaronson. Oracles are subtle but not malicious, Proceedings of IEEE Complexity 2006, 2006. arXiv:cs.CC/0504048, ECCC TR05-040.

[Aar06b] S. Aaronson. QMA/qpoly is contained in PSPACE/poly: de-Merlinizing quantum protocols, Proceedings of IEEE Complexity 2006, 2006. arXiv:quant-ph/0510230.

[Aar10] S. Aaronson. BQP and the Polynomial Hierarchy, Proceedings of ACM STOC 2010. arXiv:0910.4698, ECCC TR09-104.

[Aar18] S. Aaronson. PDQP/qpoly = ALL, arXiv:1805.08577.

[ABOE08] D. Aharonov, M. Ben-Or, E. Eban. Interactive Proofs for Quantum Computations, arXiv:0810.5375.

[AK06] S. Aaronson and G. Kuperberg. Quantum versus classical proofs and advice, submitted, 2006. arXiv:quant-ph/0604056.

[ABFL2014] S. Aaronson, A. Bouland, J. Fitzsimons, M. Lee The space "just above" BQP arXiv:arxiv.org/abs/1412.6507

[AB00] E. Allender and D. A. M. Barrington. Uniform Circuits for Division: Consequences and Problems. J. Comput. System Sci. 65 (2002), no. 4, 695--716. ECCC TR00-65, 2000.

[ABD+08] S. Aaronson, S. Beigi, A. Drucker, B. Fefferman and P. Shor. The power of unentanglement Theory of Computing, 5(1):1-42, 2009 arXiv:0804.0802

[ABF+94] J. Aspnes, R. Beigel, M. L. Furst, and S. Rudich. The expressive power of voting polynomials, Combinatorica 14(2):135-148, 1994. http://www.cs.yale.edu/~aspnes/stoc91voting.ps

[ABK+02] E. Allender, H. Buhrman, M. Koucký, D. van Melkebeek, and D. Ronneburger. Power from random strings, Proceedings of IEEE FOCS'2002, pp. 669-678, 2002. ECCC TR02-028.

[ABL98] A. Ambainis, D. M. Barrington, and H. LêThanh. On counting AC0 circuits with negative constants, Proceedings of MFCS (Mathematical Foundations of Computer Science), pp. 419-427, 1998. ECCC TR98-020.

[ABO99] E. Allender, R. Beals, and M. Ogihara. The complexity of matrix rank and feasible systems of linear equations, Computational Complexity 8(2):99-126, 1999. ECCC TR96-024, DIMACS TR 97-40.

[ABV95] W. Aiello, M. Bellare, and R. Venkatesan. Knowledge on the average - perfect, statistical, and logarithmic, Proceedings of ACM STOC'95, 1995.

[ACG+99] G. Ausiello, P. Crescenzi, G. Gambosi, V. Kann, A. Marchetti-Spaccamela, and M. Protasi. Complexity and Approximation: Combinatorial optimization problems and their approximability properties, Springer-Verlag, 1999. See also "A compendium of NP optimization problems" (P. Crescenzi and V. Kann, eds.), http://www.nada.kth.se/~viggo/wwwcompendium/.

[ACJ+21] M. Arenas, L. A. Croquevielle, R. Jayaram, and C. Riveros. #NFA admits an FPRAS: Efficient Enumeration, Counting, and Uniform Generation for Logspace Classes. Journal of the ACM 68(6):48:1-48:40, 2021.

[ADH97] L. Adleman, J. DeMarrais, and M. Huang. Quantum computability, SIAM Journal on Computing 26:1524-1540, 1997.

[Adl78] L. Adleman. Two theorems on random polynomial time. FOCS 78.

[AD14] S. Aaronson and A. Drucker. A Full Characterization of Quantum Advice, SIAM Journal on Computing 43(3):1131–1183, 2014. arXiv:1004.0377.

[AFM01] L. Antuñes, L. Fortnow, and D. van Melkebeek. Computational depth, Proceedings of IEEE Complexity'01, pp. 266-273, 2001. https://people.cs.uchicago.edu/~fortnow/papers/depth-j.pdf

[AG00] C. Alvarez and R. Greenlaw. A compendium of problems complete for symmetric logarithmic space, Journal of Computational Complexity 9:73-95, 2000. ECCC TR96-039.

[AG04] S. Aaronson and D. Gottesman. Improved Simulation of Stabilizer Circuits, Phys. Rev. A 70, 052328, 2004. arXiv:quant-ph/0406196.

[AGH90] W. Aiello, S. Goldwasser, and J. Håstad. On The Power Of Interaction. Combinatorica 10 (1990), no. 1, 3--25.

[AGK07] D. Aharonov, D. Gottesman, S. Irani, and J. Kempe;stad. The power of quantum systems on a line. Comm. Math. Physics, vol. 287, no. 1, pp. 41-65 (2009) arXiv:0705.4077

[Agr01] M. Agrawal. For completeness, sublogarithmic space is no space, Information Processing Letters (82), 2001-2002, iss. 6, 321-325. http://www.cse.iitk.ac.in/~manindra/isomorphism/sublog-completeness.pdf

[AJT83] M. Ajtai. Σ-1-1-Formulae on finite structures, Annals of Pure and Applied Logic (24), 1983, 1-48.

[AH87] L. Adleman and M. Huang. Recognizing primes in random polynomial time, Proceedings of ACM STOC'87, pp. 462-470, 1987.

[AH87b] W. Aiello and J. Håstad. Perfect zero-knowledge languages can be recognized in two rounds, Proceedings of IEEE FOCS 1987, pp. 439-448, 1987.

[AIK04] B. Applebaum, Y. Ishai, and E. Kushilevitz. Cryptography in NC0, SIAM Journal of Computing, 36(4):845-888, 2006, http://www.eng.tau.ac.il/%7Ebennyap/pubs/nc0-full.pdf.

[AJ93] C. Alvarez and B. Jenner. A very hard log-space counting class, Theoretical Computer Science 107:3-30, 1993.

[AK02] V. Arvind and P. Kurur. Graph isomorphism is in SPP, Information and Computation, 204(5):835-852, 2006 ECCC TR02-037

[AK06] S. Aaronson and G. Kuperberg. Quantum Versus Classical Proofs and Advice. Theory of Computing 3(7):129-157, 2007 https://theoryofcomputing.org/articles/v003a007/ arXiv:quant-ph/0604056

[AK96] F. Ablayev and M. Karpinski. On the power of randomized branching programs, Proceedings of the International Colloquium on Automata, Languages, and Programming (ICALP), Springer-Verlag 1099, pp. 348-356, 1996. ECCC TR95-054, DIMACS TR 96-46.

[AKL+79] R. Aleliunas, R. M. Karp, R. J. Lipton, L. Lovász, and C. Rackoff. Random walks, traversal sequences, and the complexity of maze problems, Proceedings of IEEE FOCS'79, pp. 218-223, 1979.

[AKR+03] E. Allender, M. Koucký, D. Ronneburger, et al. Derandomization and distinguishing complexity, Proceedings of the 18th Annual IEEE Conference on Computational Complexity, 209-220.

[AKS94] V. Arvind, J. Köbler and R. Schuler. On helping and interactive proof systems, Algorithms and Computation: 5th International Symposium, 137-145.

[AKS02] M. Agrawal, N. Kayal, and N. Saxena. Primes is in P, Annals of Mathematics, 160 (2004), 781-793. http://www.cse.iitk.ac.in/primality.pdf.

[AKS+95] V. Arvind, J. Köbler, U. Schöning, and R. Schuler. If NP has polynomial-size circuits, then MA=AM, Theoretical Computer Science 137, 1995. http://www.informatik.hu-berlin.de/Institut/struktur/algorithmenII/Papers/ma-am.ps.gz

[All96] E. Allender. Circuit complexity before the dawn of the new millennium, Proceedings of the 16th Annual Conference on Foundations of Software Technology and Theoretical Computer Science (FST&TCS), Lecture Notes in Computer Science 1180, pp. 1-18, 1996. DIMACS TR 97-49.

[All99] E. Allender. The permanent requires large uniform threshold circuits, Chicago Journal of Theoretical Computer Science 7, 1999. DIMACS TR 97-51.

[ALM+98] S. Arora, C. Lund, R. Motwani, M. Sudan, and M. Szegedy. Proof verification and hardness of approximation problems, Journal of the ACM 45(3):501-555, 1998. ECCC TR98-008.

[AM04] R. Alur and P. Madhusudan. Visibly Pushdown Languages, Proceedings of ACM STOC'04, 2004., 202-211.

[AM09] R. Alur and P. Madhusudan. Adding Nesting Structure to Words., Journal of the ACM 56(3), Article 16, May 2009.

[Amb14] A. Ambainis. On physical problems that are slightly more difficult than QMA, Proceedings of the 2014 IEEE 29th Conference on Computational Complexity, 2014. arXiv:quant-ph/1312.4758.

[AMP02] F. Ablayev, C. Moore, and C. Pollett. Quantum and stochastic branching programs of bounded width, Proceedings of the International Colloquium on Automata, Languages, and Programming (ICALP), 2002. arXiv:quant-ph/0201139, ECCC TR02-013.

[AMS06] N. Alon, D. Moshkovitz, and S. Safra. Algorithmic construction of sets for k-restrictions, ACM Transactions on Algorithms (TALG) 2(2): 153–177, 2006. doi:10.1145/1150334.1150336

[Ani+23] Joshua Ani et al. Complexity of Motion Planning of Arbitrarily Many Robots: Gadgets, Petri Nets, and Counter Machines. 2023. arxiv: [1]

[AN02] D. Aharonov and T. Naveh. Quantum NP - a survey, arXiv:quant-ph/0210077.

[AP95] G. Ausiello and M. Protasi Local search, reducibility, and approximability of NP optimization problems, Information Processing Letters 54:73-79, 1995.

[AR01] M. Alekhnovich and A. A. Razborov. Resolution is not automatizable unless W[P] is tractable, Proceedings of IEEE FOCS'01, pp. 210-219, 2001.

[AR03] D. Aharonov and O. Regev. A lattice problem in quantum NP, arXiv:quant-ph/0307220.

[AR88] E. Allender and R. Rubinstein. P-printable sets, SIAM Journal on Computing 17(6):1193-1202, 1988.

[AR16] B. Applebaum and P. Raykov. From Private Simultaneous Messages to Zero-Information Arthur-Merlin Protocols and Back, Proceedings of TCC(A2), pp. 65-82, 2016.

[Aro96] S. Arora. Polynomial time approximation scheme for Euclidean TSP and other geometric problems, Journal of the ACM 45(5) 753-782, 1998. https://www.cs.princeton.edu/~arora/pubs/tsp.ps

[ARZ99] E. Allender, K. Reinhardt, and S. Zhou. Isolation, matching, and counting: uniform and nonuniform upper bounds, Journal of Computer and System Sciences 59:164-181, 1999. http://www.cs.rutgers.edu/pub/allender/matching.pdf.

[AS94] E. Allender and M. Strauss. Measure on small complexity classes with applications for BPP, Proceedings of IEEE FOCS'94, pp. 807-818, 1994. ECCC TR94-004, DIMACS TR 94-18.

[AS98] S. Arora and M. Safra. Probabilistic checking of proofs: a new characterization of NP, Journal of the ACM 45(1):70-122, 1998. http://www.cs.princeton.edu/~arora/pubs/as.ps.

[ASV00] A. Ambainis, L. Schulman, and U. Vazirani. Quantum computing with highly mixed states, Proceedings of ACM STOC'2000, pp. 705-714, 2000. arXiv:quant-ph/0003136.

[ATW+00] R. Armoni, A. Ta-Shma, A. Wigderson, and S. Zhou. An O(log(n)4/3) algorithm for (s,t) connectivity in undirected graphs, Journal of the ACM 47(2):294-311, 2000. http://whiteboard.cs.tau.ac.il/~amnon/Papers/ATWZ.jacm00.pdf

[AV04] V. Arvind and T. C. Vijayaraghavan. Abelian permutation group problems and logspace counting classes, Proceedings of the 19th IEEE Conference on Computational Complexity, .

[AW09] S. Aaronson and J. Watrous. Closed Timelike Curves Make Quantum and Classical Computing Equivalent, Proceedings of the Royal Society A 465:631-647, 2009. arXiv:0808.2669.

[AW90] E. Allender and K. W. Wagner. Counting hierarchies: polynomial time and constant depth circuits, Bulletin of the EATCS 40, February 1990. http://people.cs.uchicago.edu/~fortnow/beatcs/column40.ps.

B

[Bab85] L. Babai. Trading Group Theory for Randomness. In 17th STOC, pages 421--429, 1985.

[Bab87] L. Babai. Random oracles separate PSPACE from the polynomial-time hierarchy. Information Processing Letters, 26 (1987) 51-53.

[Bar02] B. Barak. A probabilistic-time hierarchy theorem for "slightly non-uniform" algorithms, Proceedings of RANDOM'2002, 2002. http://www.math.weizmann.ac.il/~/boaz/Papers/bptime.ps

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[BB12] M. Bläser and B. Manthey. Smoothed Complexity Theory, Proceedings of the 37th Int. Symp. on Mathematical Foundations of Computer Science, 2012. ArXiv: 1202.1936.

[BB92] A. Berthiaume and G. Brassard. The quantum challenge to structural complexity theory. Proceedings of Structure in Complexity Theory, 1992, 132--137. DOI

[BBB+97] C. H. Bennett, E. Bernstein, G. Brassard, and U. Vazirani. Strengths and weaknesses of quantum computing, SIAM Journal on Computing, 26(5):1510-1523, 1997. arXiv:quant-ph/9701001.

[BBF98] R. Beigel, H. Buhrman, and L. Fortnow. NP might not be as easy as detecting unique solutions, Proceedings of ACM STOC'98, pp. 203-208, 1998. http://people.cs.uchicago.edu/~fortnow/papers/newiso.ps.

[BBR94] D. A. M. Barrington, R. Beigel, and S. Rudich. Representing Boolean functions as polynomials modulo composite integers, Computational Complexity, 4:367-382, 1994. http://www.cis.temple.edu/~beigel/papers/bbr-mods-cc.html.

[BBS86] J. Balcázar, R. Book, and U. Schöning. Sparse sets, lowness, and highness, SIAM Journal on Computing 15:739-747, 1986.

[BCE+95] P. Beame, S. Cook, J. Edmonds, R. Impagliazzo, and T. Pitassi. The relative complexity of NP search problems, Proceedings of ACM STOC'95, pp. 303-314, 1995. http://www.cs.washington.edu/homes/beame/search.ps

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[BCG+92] S. Ben-David, B. Chor, O. Goldreich, and M. Luby. On the theory of average case complexity, Journal of Computer and System Sciences 44(2):193-219, 1992. http://www.cs.technion.ac.il/~shai/aver.pdf

[BCK+14] H. Buhrman, R. Cleve, M. Koucky, B. Loff, and F. Speelman. Computing with a full memory: catalytic space, Symposium on the Theory of Computing (STOC) 857-866, 2014.

[BCS+97] L. Blum, F. Cucker, M. Shub, and S. Smale. Complexity and Real Computation, Springer-Verlag, 1997.

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[BCHTV17] A. Bouland, L. Chen, D. Holden, J. Thaler, and P. N. Vasudevan. On the Power of Statistical Zero Knowledge, Foundations of Computer Science, pp. 708-719, 2017. arXiv:[2].

[BCY11] F.G.S.L. Brandão, M. Christandl, and J. Yard. A quasipolynomial-time algorithm for the quantum separability problem. Proceedings of ACM STOC'11, pp. 343-352, 2011. arXiv:1011.2751.

[BD99] H. Buhrman and W. van Dam. Bounded quantum query complexity, Proceedings of IEEE Complexity'99, pp. 149-156, 1999. arXiv:quant-ph/9903035.

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[BDH+92] G. Buntrock, C. Damm, U. Hertrampf, and Ch. Meinel. Structure and importance of logspace-MOD-classes, Mathematical Systems Theory 25:223-237, 1992. http://www.num.math.uni-goettingen.de/damm/papers/BDHM92.ps.gz.

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[Bei94] R. Beigel. Perceptrons, PP, and the polynomial hierarchy, Computational Complexity 4:339-349, 1994. http://www.cis.temple.edu/~beigel/papers/delta2p-cc.PS.gz.

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[BF03] R. Beigel. Are Cook and Karp ever the same?, Proceedings of the 18th Annual IEEE Conference on Computational Complexity, 333-336.

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[BFM88] M. Blum, P. Feldman, and S. Micali. Non-interactive zero-knowledge proofs and their applications, Proceedings of the 20th STOC, ACM, 1988.

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[BG03] M. Ben-Or and D. Gutfreund. Trading help for interaction in statistical zero-knowledge proofs, J. Cryptology 16 (2003), no. 2, 95--116. http://www.cs.huji.ac.il/~danig/pubs/help_interaction.ps

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[BG81] C. H. Bennett and J. Gill. Relative to a random oracle A, PA != NPA != coNPA with probability 1, SIAM Journal on Computing, 10(1):96-113, 1981. DOI:10.1137/0210008

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[BG98] R. Beigel and J. Goldsmith. Downward separation fails catastrophically for limited nondeterminism classes, SIAM Journal on Computing 17(5):1420-1429, 1998. http://www.cis.temple.edu/~beigel/papers/bg-beta-draft.PS.gz.

[BG94] M. Bellare and S. Goldwasser. The complexity of decision versus search, SIAM Journal on Computing 23(1):91-119, 1994. http://www.cs.ucsd.edu/users/mihir/papers/compip.pdf

[BGG+90] M. Ben-Or, O. Goldreich, S. Goldwasser, J. Håstad, J. Kilian, S. Micali, and P. Rogaway. Everything provable is provable in zero-knowledge, Advances in Cryptology: CRYPTO'88 (S. Goldwasser, ed.), Lecture Notes in Computer Science 403, Springer-Verlag, pp. 37-56, 1990.

[BGK+88] M. Ben-Or, S. Goldwasser, J. Kilian, and A. Wigderson. Multi-prover interactive proofs: how to remove intractability, Proceedings of ACM STOC'88, pp. 113-131, 1988.

[BG82] A. Blass and Y. Gurevich. On the unique satisfiability problem, Information and Control 55(1-3):80-88, 1982.

[BGM02] E. Böhler, C. Glaßer, and D. Meister. Error-bounded probabilistic computations between MA and AM, Mathematical foundations of computer science 2003, 249--258. http://haegar.informatik.uni-wuerzburg.de/users/glasser/publications/sbp-ma-am-tr.pdf

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