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ORCIDLukas Burgholzer
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- affiliation: Technical University of Munich, Germany
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2020 – today
- 2024
[c35]Shui Jiang
, Rongliang Fu, Lukas Burgholzer, Robert Wille, Tsung-Yi Ho, Tsung-Wei Huang:
FlatDD: A High-Performance Quantum Circuit Simulator using Decision Diagram and Flat Array. ICPP 2024: 388-399- [c34]Robert Wille, Lucas Berent, Tobias Forster, Jagatheesan Kunasaikaran, Kevin Mato, Tom Peham, Nils Quetschlich, Damian Rovara, Aaron Sander, Ludwig Schmid, Daniel Schönberger, Yannick Stade, Lukas Burgholzer:
The MQT Handbook : A Summary of Design Automation Tools and Software for Quantum Computing. QSW 2024: 1-8 - [c33]Nils Quetschlich, Florian J. Kiwit, Maximilian A. Wolf, Carlos A. Riofrío, Lukas Burgholzer, Andre Luckow, Robert Wille:
Towards Application-Aware Quantum Circuit Compilation. QSW 2024: 135-142 - [c32]Aaron Sander, Ioan-Albert Florea, Lukas Burgholzer, Robert Wille:
Stripping Quantum Decision Diagrams of their Identity. QSW 2024: 168-174 - [d2]Lucas Berent, Lukas Burgholzer, Peter-Jan H. S. Derks, Jens Eisert, Robert Wille:
Dataset containing raw threshold and runtime simulation data for a paper evaluation on decoding quantum color codes. Version 2. Zenodo, 2024 [all versions]
- [i27]Yannick Stade, Ludwig Schmid, Lukas Burgholzer, Robert Wille:
An Abstract Model and Efficient Routing for Logical Entangling Gates on Zoned Neutral Atom Architectures. CoRR abs/2405.08068 (2024) - [i26]Robert Wille, Lucas Berent, Tobias Forster, Jagatheesan Kunasaikaran, Kevin Mato, Tom Peham, Nils Quetschlich, Damian Rovara, Aaron Sander, Ludwig Schmid, Daniel Schönberger, Yannick Stade, Lukas Burgholzer:
The MQT Handbook: A Summary of Design Automation Tools and Software for Quantum Computing. CoRR abs/2405.17543 (2024) - [i25]Aaron Sander, Ioan-Albert Florea, Lukas Burgholzer, Robert Wille:
Stripping Quantum Decision Diagrams of their Identity. CoRR abs/2406.11959 (2024) - 2023
- [j7]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
MQT Bench: Benchmarking Software and Design Automation Tools for Quantum Computing. Quantum 7: 1062 (2023) - [j6]Lukas Burgholzer, Alexander Ploier, Robert Wille:
Simulation Paths for Quantum Circuit Simulation With Decision Diagrams What to Learn From Tensor Networks, and What Not. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 42(4): 1113-1122 (2023) - [c31]Sarah Schneider, Lukas Burgholzer, Robert Wille:
A SAT Encoding for Optimal Clifford Circuit Synthesis. ASP-DAC 2023: 190-195 - [c30]Lukas Burgholzer, Robert Wille:
Exploiting Reversible Computing for Verification: Potential, Possible Paths, and Consequences. ASP-DAC 2023: 429-435 - [c29]Tom Peham, Lukas Burgholzer, Robert Wille:
Equivalence Checking of Parameterized Quantum Circuits: Verifying the Compilation of Variational Quantum Algorithms. ASP-DAC 2023: 702-708 - [c28]Lucas Berent, Lukas Burgholzer, Robert Wille:
Software Tools for Decoding Quantum Low-Density Parity-Check Codes. ASP-DAC 2023: 709-714 - [c27]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Compiler Optimization for Quantum Computing Using Reinforcement Learning. DAC 2023: 1-6 - [c26]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Towards an Automated Framework for Realizing Quantum Computing Solutions. ISMVL 2023: 134-140 - [c25]Robert Wille, Lukas Burgholzer:
MQT QMAP: Efficient Quantum Circuit Mapping. ISPD 2023: 198-204 - [c24]Aaron Sander, Lukas Burgholzer, Robert Wille:
Towards Hamiltonian Simulation with Decision Diagrams. QCE 2023: 283-294 - [c23]Nils Quetschlich, Vincent Koch, Lukas Burgholzer, Robert Wille:
A Hybrid Classical Quantum Computing Approach to the Satellite Mission Planning Problem. QCE 2023: 642-647 - [c22]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Reducing the Compilation Time of Quantum Circuits Using Pre-Compilation on the Gate Level. QCE 2023: 757-767 - [c21]Tom Peham, Nina Brandl, Richard Kueng, Robert Wille, Lukas Burgholzer:
Depth-Optimal Synthesis of Clifford Circuits with SAT Solvers. QCE 2023: 802-813 - [c20]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Predicting Good Quantum Circuit Compilation Options. QSW 2023: 43-53 - [c19]Benedikt Poggel, Nils Quetschlich, Lukas Burgholzer, Robert Wille, Jeanette Miriam Lorenz:
Recommending Solution Paths for Solving Optimization Problems with Quantum Computing. QSW 2023: 60-67 - [p1]Lukas Burgholzer:
Entwurfsautomatisierungs-Tools und Software für Quantencomputing. Ausgezeichnete Informatikdissertationen 2023: 41-50 - [d1]Lucas Berent, Lukas Burgholzer, Peter-Jan H. S. Derks, Jens Eisert, Robert Wille:
Dataset containing raw threshold and runtime simulation data for a paper evaluation on decoding quantum color codes. Version 1. Zenodo, 2023 [all versions] - [i24]Robert Wille, Lukas Burgholzer, Stefan Hillmich, Thomas Grurl, Alexander Ploier, Tom Peham:
The Basis of Design Tools for Quantum Computing: Arrays, Decision Diagrams, Tensor Networks, and ZX-Calculus. CoRR abs/2301.04147 (2023) - [i23]Robert Wille, Lukas Burgholzer:
MQT QMAP: Efficient Quantum Circuit Mapping. CoRR abs/2301.11935 (2023) - [i22]Lukas Burgholzer, Alexander Ploier, Robert Wille:
Tensor Networks or Decision Diagrams? Guidelines for Classical Quantum Circuit Simulation. CoRR abs/2302.06616 (2023) - [i21]Tom Peham, Nina Brandl, Richard Kueng, Robert Wille, Lukas Burgholzer:
Depth-Optimal Synthesis of Clifford Circuits with SAT Solvers. CoRR abs/2305.01674 (2023) - [i20]Aaron Sander, Lukas Burgholzer, Robert Wille:
Towards Hamiltonian Simulation with Decision Diagrams. CoRR abs/2305.02337 (2023) - 2022
- [j5]Lukas Burgholzer, Robert Wille, Richard Kueng:
Characteristics of reversible circuits for error detection. Array 14: 100165 (2022) - [j4]Tom Peham, Lukas Burgholzer, Robert Wille:
Equivalence Checking of Quantum Circuits With the ZX-Calculus. IEEE J. Emerg. Sel. Topics Circuits Syst. 12(3): 662-675 (2022) - [j3]Smaran Adarsh, Lukas Burgholzer, Tanmay Manjunath, Robert Wille:
SyReC Synthesizer: An MQT tool for synthesis of reversible circuits. Softw. Impacts 14: 100451 (2022) - [c18]Lukas Burgholzer, Sarah Schneider, Robert Wille:
Limiting the Search Space in Optimal Quantum Circuit Mapping. ASP-DAC 2022: 466-471 - [c17]Tom Peham, Lukas Burgholzer, Robert Wille:
Equivalence checking paradigms in quantum circuit design: a case study. DAC 2022: 517-522 - [c16]Lukas Burgholzer, Robert Wille:
Handling non-unitaries in quantum circuit equivalence checking. DAC 2022: 529-534 - [c15]Robert Wille, Lukas Burgholzer, Stefan Hillmich, Thomas Grurl, Alexander Ploier, Tom Peham:
The basis of design tools for quantum computing: arrays, decision diagrams, tensor networks, and ZX-calculus. DAC 2022: 1367-1370 - [c14]Lukas Burgholzer, Alexander Ploier, Robert Wille:
Exploiting Arbitrary Paths for the Simulation of Quantum Circuits with Decision Diagrams. DATE 2022: 64-67 - [c13]Stefan Hillmich, Lukas Burgholzer, Florian Stögmüller, Robert Wille:
Reordering Decision Diagrams for Quantum Computing Is Harder Than You Might Think. RC 2022: 93-107 - [c12]Lucas Berent, Lukas Burgholzer, Robert Wille:
Towards a SAT Encoding for Quantum Circuits: A Journey From Classical Circuits to Clifford Circuits and Beyond. SAT 2022: 18:1-18:17 - [i19]Lucas Berent, Lukas Burgholzer, Robert Wille:
Towards a SAT Encoding for Quantum Circuits: A Journey From Classical Circuits to Clifford Circuits and Beyond. CoRR abs/2203.00698 (2022) - [i18]Lukas Burgholzer, Alexander Ploier, Robert Wille:
Simulation Paths for Quantum Circuit Simulation with Decision Diagrams. CoRR abs/2203.00703 (2022) - [i17]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
MQT Bench: Benchmarking Software and Design Automation Tools for Quantum Computing. CoRR abs/2204.13719 (2022) - [i16]Sarah Schneider, Lukas Burgholzer, Robert Wille:
A SAT Encoding for Optimal Clifford Circuit Synthesis. CoRR abs/2208.11713 (2022) - [i15]Tom Peham, Lukas Burgholzer, Robert Wille:
Equivalence Checking of Quantum Circuits with the ZX-Calculus. CoRR abs/2208.12820 (2022) - [i14]Lucas Berent, Lukas Burgholzer, Robert Wille:
Software Tools for Decoding Quantum Low-Density Parity Check Codes. CoRR abs/2209.01180 (2022) - [i13]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Predicting Good Quantum Circuit Compilation Options. CoRR abs/2210.08027 (2022) - [i12]Tom Peham, Lukas Burgholzer, Robert Wille:
On Optimal Subarchitectures for Quantum Circuit Mapping. CoRR abs/2210.09321 (2022) - [i11]Tom Peham, Lukas Burgholzer, Robert Wille:
Equivalence Checking of Parameterized Quantum Circuits: Verifying the Compilation of Variational Quantum Algorithms. CoRR abs/2210.12166 (2022) - [i10]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Towards an Automated Framework for Realizing Quantum Computing Solutions. CoRR abs/2210.14928 (2022) - [i9]Nils Quetschlich, Lukas Burgholzer, Robert Wille:
Compiler Optimization for Quantum Computing Using Reinforcement Learning. CoRR abs/2212.04508 (2022) - [i8]Smaran Adarsh, Lukas Burgholzer, Tanmay Manjunath, Robert Wille:
SyReC Synthesizer: An MQT tool for synthesis of reversible circuits. CoRR abs/2212.05903 (2022) - 2021
- [j2]Lukas Burgholzer, Robert Wille:
QCEC: A JKQ tool for quantum circuit equivalence checking. Softw. Impacts 7: 100051 (2021) - [j1]Lukas Burgholzer, Robert Wille:
Advanced Equivalence Checking for Quantum Circuits. IEEE Trans. Comput. Aided Des. Integr. Circuits Syst. 40(9): 1810-1824 (2021) - [c11]Lukas Burgholzer, Richard Kueng, Robert Wille:
Random Stimuli Generation for the Verification of Quantum Circuits. ASP-DAC 2021: 767-772 - [c10]Robert Wille, Lukas Burgholzer, Michael Artner:
Visualizing Decision Diagrams for Quantum Computing (Special Session Summary). DATE 2021: 768-773 - [c9]Lukas Burgholzer, Hartwig Bauer, Robert Wille:
Hybrid Schrödinger-Feynman Simulation of Quantum Circuits With Decision Diagrams. QCE 2021: 199-206 - [c8]Lukas Burgholzer, Rudy Raymond, Indranil Sengupta, Robert Wille:
Efficient Construction of Functional Representations for Quantum Algorithms. RC 2021: 227-241 - [i7]Lukas Burgholzer, Rudy Raymond, Indranil Sengupta, Robert Wille:
Efficient Construction of Functional Representations for Quantum Algorithms. CoRR abs/2103.08281 (2021) - [i6]Lukas Burgholzer, Hartwig Bauer, Robert Wille:
Hybrid Schrödinger-Feynman Simulation of Quantum Circuits With Decision Diagrams. CoRR abs/2105.07045 (2021) - [i5]Lukas Burgholzer, Robert Wille:
Towards Verification of Dynamic Quantum Circuits. CoRR abs/2106.01099 (2021) - [i4]Lukas Burgholzer, Sarah Schneider, Robert Wille:
Limiting the Search Space in Optimal Quantum Circuit Mapping. CoRR abs/2112.00045 (2021) - 2020
- [c7]Lukas Burgholzer, Robert Wille:
Improved DD-based Equivalence Checking of Quantum Circuits. ASP-DAC 2020: 127-132 - [c6]Lukas Burgholzer, Robert Wille:
The Power of Simulation for Equivalence Checking in Quantum Computing. DAC 2020: 1-6 - [c5]Robert Wille, Stefan Hillmich, Lukas Burgholzer:
JKQ: JKU Tools for Quantum Computing. ICCAD 2020: 154:1-154:5 - [c4]Robert Wille, Stefan Hillmich, Lukas Burgholzer:
Efficient and Correct Compilation of Quantum Circuits. ISCAS 2020: 1-5 - [c3]Thomas Grurl, Jürgen Fuß, Stefan Hillmich, Lukas Burgholzer, Robert Wille:
Arrays vs. Decision Diagrams: A Case Study on Quantum Circuit Simulators. ISMVL 2020: 176-181 - [c2]Lukas Burgholzer, Rudy Raymond, Robert Wille:
Verifying Results of the IBM Qiskit Quantum Circuit Compilation Flow. QCE 2020: 356-365 - [i3]Lukas Burgholzer, Robert Wille:
Advanced Equivalence Checking for Quantum Circuits. CoRR abs/2004.08420 (2020) - [i2]Lukas Burgholzer, Richard Kueng, Robert Wille:
Random Stimuli Generation for the Verification of Quantum Circuits. CoRR abs/2011.07288 (2020) - [i1]Lukas Burgholzer, Robert Wille, Richard Kueng:
Characteristics of Reversible Circuits for Error Detection. CoRR abs/2012.02037 (2020)
2010 – 2019
- 2019
- [c1]Robert Wille, Lukas Burgholzer, Alwin Zulehner:
Mapping Quantum Circuits to IBM QX Architectures Using the Minimal Number of SWAP and H Operations. DAC 2019: 142
Coauthor Index
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last updated on 2024-10-07 02:28 CEST by the dblp team
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