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Publication search results
found 33 matches
- 2025
- Stephen Whitelam:
Generative thermodynamic computing. CoRR abs/2506.15121 (2025) - 2024
- Emma Crisci, Maxime Mahout
, Sabine Peres:
Computing Thermodynamically Consistent Elementary Flux Modes with Answer Set Programming. CMSB 2024: 80-88 - Maxwell Aifer, Denis Melanson, Kaelan Donatella, Gavin E. Crooks, Thomas Ahle, Patrick J. Coles:
Error Mitigation for Thermodynamic Computing. CoRR abs/2401.16231 (2024) - Prateek Sharma:
The Jevons Paradox In Cloud Computing: A Thermodynamics Perspective. CoRR abs/2411.11540 (2024) - Stephen Whitelam, Corneel Casert:
Thermodynamic computing out of equilibrium. CoRR abs/2412.17183 (2024) - 2023
- George Dan Miron
ThermoFun: A C++/Python library for computing standard thermodynamic properties of substances and reactions across wide ranges of temperatures and pressures. J. Open Source Softw. 8(83): 4624 (2023) - Sergey V. Ulyanov, Viktor S. Ulyanov, Takahide Hagiwara:
Robust Quantum Controllers: Quantum Information - Thermodynamic Hidden Force Control in Intelligent Robotics based on Quantum Soft Computing. CoRR abs/2305.11254 (2023) - Christian Z. Pratt, Kyle J. Ray, James P. Crutchfield:
Dynamical Computing on the Nanoscale: Superconducting Circuits for Thermodynamically-Efficient Classical Information Processing. CoRR abs/2307.01926 (2023) - Patryk Lipka-Bartosik, Martí Perarnau-Llobet, Nicolas Brunner:
Thermodynamic Computing via Autonomous Quantum Thermal Machines. CoRR abs/2308.15905 (2023) - Denis Melanson, Mohammad Abu Khater, Maxwell Aifer, Kaelan Donatella, Max Hunter Gordon, Thomas Ahle, Gavin E. Crooks, Antonio J. Martinez, Faris M. Sbahi, Patrick J. Coles:
Thermodynamic Computing System for AI Applications. CoRR abs/2312.04836 (2023) - 2022
- Xiaolong He:
Thermodynamically Consistent Physics-Informed Data-Driven Computing and Reduced-Order Modeling of Nonlinear Materials. University of California, San Diego, USA, 2022 - 2021
- Peijia Ren, Zeshui Xu:
Decision-Making Analyses with Thermodynamic Parameters and Hesitant Fuzzy Linguistic Preference Relations. Studies in Fuzziness and Soft Computing 409, Springer 2021, ISBN 978-3-030-73252-3, pp. 1-130 - Samuel A. Cushman:
Thermodynamic Consistency of the Cushman Method of Computing the Configurational Entropy of a Landscape Lattice. Entropy 23(11): 1420 (2021) - Mozhdeh Tanha
A hybrid meta-heuristic task scheduling algorithm based on genetic and thermodynamic simulated annealing algorithms in cloud computing environments. Neural Comput. Appl. 33(24): 16951-16984 (2021) - David Haley, David Doty
Computing Properties of Thermodynamic Binding Networks: An Integer Programming Approach. DNA 2021: 2:1-2:16 - 2020
- Alexis De Vos:
Endoreversible Models for the Thermodynamics of Computing. Entropy 22(6): 660 (2020) - David Haley, David Doty:
Computing Properties of Thermodynamic Binding Networks: An Integer Programming Approach. CoRR abs/2011.10677 (2020) - 2019
- Keenan Breik, Chris Thachuk, Marijn Heule, David Soloveichik
Computing properties of stable configurations of thermodynamic binding networks. Theor. Comput. Sci. 785: 17-29 (2019) - Gregory Wimsatt, Olli-Pentti Saira, Alexander B. Boyd, Matthew H. Matheny, Siyuan Han, Michael L. Roukes, James P. Crutchfield:
Harnessing Fluctuations in Thermodynamic Computing via Time-Reversal Symmetries. CoRR abs/1906.11973 (2019) - Tom Conte, Erik DeBenedictis, Natesh Ganesh, Todd Hylton, John Paul Strachan, R. Stanley Williams, Alexander A. Alemi, Lee Altenberg, Gavin E. Crooks, James P. Crutchfield, Lídia del Rio
Thermodynamic Computing. CoRR abs/1911.01968 (2019) - 2018
- Alexander B. Boyd, Ayoti Patra, C. Jarzynski, James P. Crutchfield:
Shortcuts to Thermodynamic Computing: The Cost of Fast and Faithful Erasure. CoRR abs/1812.11241 (2018) - 2017
- Robert L. Fry:
Physical Intelligence and Thermodynamic Computing. Entropy 19(3): 107 (2017) - Robert C. Harris, Nan-Jie Deng, Ronald M. Levy, Ryosuke Ishizuka, Nobuyuki Matubayasi
Computing conformational free energy differences in explicit solvent: An efficient thermodynamic cycle using an auxiliary potential and a free energy functional constructed from the end points. J. Comput. Chem. 38(15): 1198-1208 (2017) - Keenan Breik, Lakshmi Prakash, Chris Thachuk, Marijn Heule, David Soloveichik:
Computing properties of stable configurations of thermodynamic binding networks. CoRR abs/1709.08731 (2017) - 2015
- Matthias P. Gerstl, Christian Jungreuthmayer, Jürgen Zanghellini
tEFMA: computing thermodynamically feasible elementary flux modes in metabolic networks. Bioinform. 31(13): 2232-2234 (2015) - 2013
- Stefan Eckelsbach, Svetlana Miroshnichenko, Gábor Rutkai, Jadran Vrabec
Surface Tension, Large Scale Thermodynamic Data Generation and Vapor-Liquid Equilibria of Real Compounds. High Performance Computing in Science and Engineering 2013: 635-646 - Stefan Krieg
Report: Thermodynamics with $2 + 1 + 1$ Dynamical Quark Flavors. High Performance Computing in Science and Engineering 2013: 65-72 - 2011
- Frieder Hadlich, Katharina Nöh
Determination of flux directions by thermodynamic network analysis: Computing informative metabolite pools. Math. Comput. Simul. 82(3): 460-470 (2011) - 2009
- John S. Hamel:
A Thermodynamic Turing Machine: Artificial Molecular Computing Using Classical Reversible Logic Switching Networks. CoRR abs/0904.3273 (2009) - 2007
- Guha Jayachandran:
Parallel computing methods for probing biomolecular kinetics and thermodynamics. Stanford University, USA, 2007
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