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2020 – today
- 2024
[j12]Emmanuel Jeandel, Simon Perdrix, Margarita Veshchezerova:
Addition and Differentiation of ZX-diagrams. Log. Methods Comput. Sci. 20(2) (2024)- [c55]Alexandre Clément
, Noé Delorme, Simon Perdrix, Renaud Vilmart:
Quantum Circuit Completeness: Extensions and Simplifications. CSL 2024: 20:1-20:23 - [c54]Martin Avanzini, Georg Moser, Romain Péchoux, Simon Perdrix:
On the Hardness of Analyzing Quantum Programs Quantitatively. ESOP (2) 2024: 31-58 - [c53]Maxime Cautrès, Nathan Claudet, Mehdi Mhalla, Simon Perdrix, Valentin Savin, Stéphan Thomassé:
Vertex-Minor Universal Graphs for Generating Entangled Quantum Subsystems. ICALP 2024: 36:1-36:18 - [c52]Alexandre Clément, Noé Delorme, Simon Perdrix:
Minimal Equational Theories for Quantum Circuits. LICS 2024: 27:1-27:14 - [i28]Maxime Cautrès, Nathan Claudet, Mehdi Mhalla, Simon Perdrix, Valentin Savin, Stéphan Thomassé:
Vertex-minor universal graphs for generating entangled quantum subsystems. CoRR abs/2402.06260 (2024) - [i27]Nathan Claudet, Simon Perdrix:
Covering a Graph with Minimal Local Sets. CoRR abs/2402.10678 (2024) - [i26]Nathan Claudet, Simon Perdrix:
Local equivalence of stabilizer states: a graphical characterisation. CoRR abs/2409.20183 (2024) - 2023
- [c51]Alexandre Clément, Nicolas Heurtel, Shane Mansfield, Simon Perdrix, Benoît Valiron:
A Complete Equational Theory for Quantum Circuits. LICS 2023: 1-13 - [i25]Alexandre Clément, Noé Delorme, Simon Perdrix, Renaud Vilmart:
Simple Complete Equational Theories for Quantum Circuits with Ancillae or Partial Trace. CoRR abs/2303.03117 (2023) - [i24]Alexandre Clément, Noé Delorme, Simon Perdrix:
Minimal Equational Theories for Quantum Circuits. CoRR abs/2311.07476 (2023) - [i23]Martin Avanzini, Georg Moser, Romain Péchoux, Simon Perdrix:
On the Hardness of Analyzing Quantum Programs Quantitatively. CoRR abs/2312.13657 (2023) - 2022
- [c50]Emmanuel Jeandel, Simon Perdrix, Margarita Veshchezerova:
Addition and Differentiation of ZX-Diagrams. FSCD 2022: 13:1-13:19 - [c49]Martin Avanzini, Georg Moser, Romain Péchoux, Simon Perdrix, Vladimir Zamdzhiev:
Quantum Expectation Transformers for Cost Analysis. LICS 2022: 10:1-10:13 - [c48]Alexandre Clément, Nicolas Heurtel, Shane Mansfield, Simon Perdrix, Benoît Valiron:
LO_v-Calculus: A Graphical Language for Linear Optical Quantum Circuits. MFCS 2022: 35:1-35:16 - [c47]Alexandre Clément, Simon Perdrix:
Resource Optimisation of Coherently Controlled Quantum Computations with the PBS-Calculus. MFCS 2022: 36:1-36:15 - [i22]Martin Avanzini, Georg Moser, Romain Péchoux, Simon Perdrix, Vladimir Zamdzhiev:
Quantum Expectation Transformers for Cost Analysis. CoRR abs/2201.09361 (2022) - [i21]Alexandre Clément, Nicolas Heurtel, Shane Mansfield, Simon Perdrix, Benoît Valiron:
LOv-Calculus: A Graphical Language for Linear Optical Quantum Circuits. CoRR abs/2204.11787 (2022) - 2021
- [c46]Agustín Borgna, Simon Perdrix, Benoît Valiron:
Hybrid Quantum-Classical Circuit Simplification with the ZX-Calculus. APLAS 2021: 121-139 - [c45]Titouan Carette, Marc de Visme, Simon Perdrix:
Graphical Language with Delayed Trace: Picturing Quantum Computing with Finite Memory. LICS 2021: 1-13 - [c44]Cyril Branciard, Alexandre Clément, Mehdi Mhalla, Simon Perdrix:
Coherent Control and Distinguishability of Quantum Channels via PBS-Diagrams. MFCS 2021: 22:1-22:20 - [c43]Titouan Carette, Yohann D'Anello, Simon Perdrix:
Quantum Algorithms and Oracles with the Scalable ZX-calculus. QPL 2021: 193-209 - [i20]Cyril Branciard, Alexandre Clément, Mehdi Mhalla, Simon Perdrix:
Coherent control and distinguishability of quantum channels via PBS-diagrams. CoRR abs/2103.02073 (2021) - 2020
- [j11]Anurag Anshu, Peter Høyer, Mehdi Mhalla, Simon Perdrix:
Contextuality in multipartite pseudo-telepathy graph games. J. Comput. Syst. Sci. 107: 156-165 (2020) - [j10]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
Completeness of the ZX-Calculus. Log. Methods Comput. Sci. 16(2) (2020) - [j9]Miriam Backens, Simon Perdrix, Quanlong Wang:
Towards a Minimal Stabilizer ZX-calculus. Log. Methods Comput. Sci. 16(4) (2020) - [j8]Pablo Arrighi, Simon Martiel, Simon Perdrix:
Reversible causal graph dynamics: invertibility, block representation, vertex-preservation. Nat. Comput. 19(1): 157-178 (2020) - [j7]Ross Duncan, Aleks Kissinger, Simon Perdrix, John van de Wetering:
Graph-theoretic Simplification of Quantum Circuits with the ZX-calculus. Quantum 4: 279 (2020) - [c42]Romain Péchoux, Simon Perdrix, Mathys Rennela, Vladimir Zamdzhiev:
Quantum Programming with Inductive Datatypes: Causality and Affine Type Theory. FoSSaCS 2020: 562-581 - [c41]Alexandre Clément, Simon Perdrix:
PBS-Calculus: A Graphical Language for Coherent Control of Quantum Computations. MFCS 2020: 24:1-24:14 - [p2]Olivier Bournez, Gilles Dowek, Rémi Gilleron, Serge Grigorieff, Jean-Yves Marion, Simon Perdrix, Sophie Tison:
Theoretical Computer Science: Computability, Decidability and Logic. A Guided Tour of Artificial Intelligence Research (3) (III) 2020: 1-50 - [p1]Olivier Bournez, Gilles Dowek, Rémi Gilleron, Serge Grigorieff, Jean-Yves Marion, Simon Perdrix, Sophie Tison:
Theoretical Computer Science: Computational Complexity. A Guided Tour of Artificial Intelligence Research (3) (III) 2020: 51-89 - [i19]Alexandre Clément, Simon Perdrix:
PBS-calculus: A Graphical Language for Quantum-Controlled Computations. CoRR abs/2002.09387 (2020) - [i18]Titouan Carette, Simon Perdrix:
Colored props for large scale graphical reasoning. CoRR abs/2007.03564 (2020)
2010 – 2019
- 2019
- [b2]Simon Perdrix:
Approches Graphiques en Informatique Quantique. University of Lorraine, Nancy, France, 2019 - [c40]Titouan Carette, Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
Completeness of Graphical Languages for Mixed States Quantum Mechanics. ICALP 2019: 108:1-108:15 - [c39]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
A Generic Normal Form for ZX-Diagrams and Application to the Rational Angle Completeness. LICS 2019: 1-10 - [c38]Titouan Carette, Dominic Horsman, Simon Perdrix:
SZX-Calculus: Scalable Graphical Quantum Reasoning. MFCS 2019: 55:1-55:15 - [c37]Niel de Beaudrap, Ross Duncan, Dominic Horsman, Simon Perdrix:
Pauli Fusion: a Computational Model to Realise Quantum Transformations from ZX Terms. QPL 2019: 85-105 - [i17]Ross Duncan, Aleks Kissinger, Simon Perdrix, John van de Wetering:
Graph-theoretic Simplification of Quantum Circuits with the ZX-calculus. CoRR abs/1902.03178 (2019) - [i16]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
Completeness of the ZX-Calculus. CoRR abs/1903.06035 (2019) - [i15]Romain Péchoux, Simon Perdrix, Mathys Rennela, Vladimir Zamdzhiev:
Quantum Programming with Inductive Datatypes: Causality and Affine Type Theory. CoRR abs/1910.09633 (2019) - 2018
- [c36]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
A Complete Axiomatisation of the ZX-Calculus for Clifford+T Quantum Mechanics. LICS 2018: 559-568 - [c35]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
Diagrammatic Reasoning beyond Clifford+T Quantum Mechanics. LICS 2018: 569-578 - [i14]Jop Briët, Simon Perdrix:
Quantum Computation and Information - Introduction to the Special Theme. ERCIM News 2018(112) (2018) - 2017
- [c34]Anurag Anshu, Peter Høyer, Mehdi Mhalla, Simon Perdrix:
Contextuality in Multipartite Pseudo-Telepathy Graph Games. FCT 2017: 41-55 - [c33]Simon Perdrix, Luc Sanselme:
Determinism and Computational Power of Real Measurement-Based Quantum Computation. FCT 2017: 395-408 - [c32]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart, Quanlong Wang:
ZX-Calculus: Cyclotomic Supplementarity and Incompleteness for Clifford+T Quantum Mechanics. MFCS 2017: 11:1-11:13 - [c31]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart:
Y-Calculus: A language for real Matrices derived from the ZX-Calculus. QPL 2017: 23-57 - [i13]Emmanuel Jeandel, Simon Perdrix, Renaud Vilmart, Quanlong Wang:
Generalised Supplementarity and new rule for Empty Diagrams to Make the ZX-Calculus More Expressive. CoRR abs/1702.01945 (2017) - [i12]Samson Abramsky, Rui Soares Barbosa, Giovanni Carù, Simon Perdrix:
A complete characterisation of All-versus-Nothing arguments for stabiliser states. CoRR abs/1705.08459 (2017) - [i11]Miriam Backens, Simon Perdrix, Quanlong Wang:
Towards a Minimal Stabilizer ZX-calculus. CoRR abs/1709.08903 (2017) - 2016
- [c30]Simon Perdrix, Quanlong Wang:
Supplementarity is Necessary for Quantum Diagram Reasoning. MFCS 2016: 76:1-76:14 - [c29]Pablo Arrighi, Simon Martiel, Simon Perdrix:
Reversible Causal Graph Dynamics. RC 2016: 73-88 - [c28]Miriam Backens, Simon Perdrix, Quanlong Wang:
A Simplified Stabilizer ZX-calculus. QPL 2016: 1-20 - [i10]Peter Høyer, Mehdi Mhalla, Simon Perdrix:
Contextuality in multipartie pseudo-telepathy graph games. CoRR abs/1609.09689 (2016) - 2015
- [j6]Sylvain Gravier, Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
On weak odd domination and graph-based quantum secret sharing. Theor. Comput. Sci. 598: 129-137 (2015) - [c27]Pablo Arrighi, Simon Martiel, Simon Perdrix:
Block Representation of Reversible Causal Graph Dynamics. FCT 2015: 351-363 - [c26]David Cattanéo, Simon Perdrix:
Minimum Degree Up to Local Complementation: Bounds, Parameterized Complexity, and Exact Algorithms. ISAAC 2015: 259-270 - [c25]Nidhal Hamrit, Simon Perdrix:
Reversibility in Extended Measurement-Based Quantum Computation. RC 2015: 129-138 - [c24]Stefano Facchini, Simon Perdrix:
Quantum Circuits for the Unitary Permutation Problem. TAMC 2015: 324-331 - [i9]Pablo Arrighi, Simon Martiel, Simon Perdrix:
Reversible Causal Graph Dynamics. CoRR abs/1502.04368 (2015) - [i8]Nidhal Hamrit, Simon Perdrix:
Reversibility in the Extended Measurement-based Quantum Computation. CoRR abs/1503.03008 (2015) - [i7]David Cattanéo, Simon Perdrix:
Minimum Degree up to Local Complementation: Bounds, Parameterized Complexity, and Exact Algorithms. CoRR abs/1503.04702 (2015) - 2014
- [j5]Ali Assaf, Alejandro Díaz-Caro, Simon Perdrix, Christine Tasson, Benoît Valiron:
Call-by-value, call-by-name and the vectorial behaviour of the algebraic λ-calculus. Log. Methods Comput. Sci. 10(4) (2014) - [c23]David Cattanéo, Simon Perdrix:
The Parameterized Complexity of Domination-Type Problems and Application to Linear Codes. TAMC 2014: 86-103 - 2013
- [j4]Mehdi Mhalla, Simon Perdrix:
Graph States, Pivot Minor, and Universality of (X, Z)-Measurements. Int. J. Unconv. Comput. 9(1-2): 153-171 (2013) - [c22]David Cattanéo, Simon Perdrix:
Parameterized Complexity of Weak Odd Domination Problems. FCT 2013: 107-120 - [c21]Anne Marin, Damian Markham, Simon Perdrix:
Access Structure in Graphs in High Dimension and Application to Secret Sharing. TQC 2013: 308-324 - [c20]Ross Duncan, Simon Perdrix:
Pivoting makes the ZX-calculus complete for real stabilizers. QPL 2013: 50-62 - 2012
- [c19]Sylvain Gravier, Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
Quantum Secret Sharing with Graph States. MEMICS 2012: 15-31 - [c18]Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
New Protocols and Lower Bounds for Quantum Secret Sharing with Graph States. TQC 2012: 1-12 - [c17]Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
On the Minimum Degree Up to Local Complementation: Bounds and Complexity. WG 2012: 138-147 - [i6]Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
On the Minimum Degree up to Local Complementation: Bounds and Complexity. CoRR abs/1204.4564 (2012) - [i5]David Cattanéo, Simon Perdrix:
Parametrized Complexity of Weak Odd Domination Problems. CoRR abs/1206.4081 (2012) - [i4]David Cattanéo, Simon Perdrix:
The Parameterized Complexity of Domination-type Problems and Application to Linear Codes. CoRR abs/1209.5267 (2012) - 2011
- [j3]Simon Perdrix:
Towards Observable Quantum Turing Machines: Fundamentals, Computational Power, and Universality. Int. J. Unconv. Comput. 7(4): 291-311 (2011) - [c16]Mehdi Mhalla, Mio Murao, Simon Perdrix, Masato Someya, Peter S. Turner:
Which Graph States are Useful for Quantum Information Processing? TQC 2011: 174-187 - [c15]Ali Assaf, Simon Perdrix:
Completeness of algebraic CPS simulations. DCM 2011: 16-27 - [i3]Sylvain Gravier, Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
Optimal accessing and non-accessing structures for graph protocols. CoRR abs/1109.6181 (2011) - [i2]Sylvain Gravier, Jérôme Javelle, Mehdi Mhalla, Simon Perdrix:
On Weak Odd Domination and Graph-based Quantum Secret Sharing. CoRR abs/1112.2495 (2011) - 2010
- [j2]Bob Coecke, Simon Perdrix:
Environment and classical channels in categorical quantum mechanics. Log. Methods Comput. Sci. 8(4) (2010) - [c14]Bob Coecke, Simon Perdrix:
Environment and Classical Channels in Categorical Quantum Mechanics. CSL 2010: 230-244 - [c13]Ross Duncan, Simon Perdrix:
Rewriting Measurement-Based Quantum Computations with Generalised Flow. ICALP (2) 2010: 285-296 - [c12]Dan E. Browne, Elham Kashefi, Simon Perdrix:
Computational Depth Complexity of Measurement-Based Quantum Computation. TQC 2010: 35-46
2000 – 2009
- 2009
- [c11]Ross Duncan, Simon Perdrix:
Graph States and the Necessity of Euler Decomposition. CiE 2009: 167-177 - [c10]Elham Kashefi, Damian Markham, Mehdi Mhalla, Simon Perdrix:
Information Flow in Secret Sharing Protocols. DCM 2009: 87-97 - 2008
- [c9]Mehdi Mhalla, Simon Perdrix:
Finding Optimal Flows Efficiently. ICALP (1) 2008: 857-868 - [c8]Simon Perdrix:
Quantum Entanglement Analysis Based on Abstract Interpretation. SAS 2008: 270-282 - [c7]Simon Perdrix:
Partial Observation of Quantum Turing Machines and a Weaker Well-Formedness Condition. QPL/DCM@ICALP 2008: 99-111 - [c6]Bob Coecke, Simon Perdrix, Éric Oliver Paquette:
Bases in Diagrammatic Quantum Protocols. MFPS 2008: 131-152 - [i1]Simon Perdrix:
Quantum entanglement analysis based on abstract interpretation. CoRR abs/0801.4230 (2008) - 2007
- [c5]Simon Perdrix:
A Hierarchy of Quantum Semantics. DCM@ICALP 2007: 71-83 - 2006
- [b1]Simon Perdrix:
Modèles formels du calcul quantique : ressources, machines abstraites et calcul par mesure. (Formal models of quantum computing: resources, abstract machines and measurement-based quantum computing). Grenoble Institute of Technology, France, 2006 - [j1]Simon Perdrix, Philippe Jorrand:
Classically controlled quantum computation. Math. Struct. Comput. Sci. 16(4): 601-620 (2006) - [c4]Peter Høyer, Mehdi Mhalla, Simon Perdrix:
Resources Required for Preparing Graph States. ISAAC 2006: 638-649 - [c3]Philippe Jorrand, Simon Perdrix:
Towards a Quantum Calculus: (Work in Progress, Extended Abstract). QPL 2006: 75-83 - 2005
- [c2]Simon Perdrix, Philippe Jorrand:
Classically-controlled Quantum Computation. DCM@ICALP 2005: 119-128 - [c1]Simon Perdrix:
Quantum Patterns and Types for Entanglement and Separability. QPL 2005: 125-138
Coauthor Index
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last updated on 2024-10-22 20:16 CEST by the dblp team
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