Characterizing Molecular Dynamics Simulation on Commodity Platforms

Peverelli, Francesco; Conficconi, Davide; Bartolini, Davide B.; Scolari, Alberto; Santambrogio, Marco D.

doi:10.1109/iiswc55918.2022.00016

Cited by 3 publications

(2 citation statements)

References 32 publications

(40 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Regardless of the specific application's field, more advanced hardware in memory and resources is necessary [55]. Indeed, this problem affects all disciplines more broadly related to molecular dynamics [64], which could substantially benefit from quantum acceleration for the same reasons.…”

Section: Quantum Random Access Memorymentioning

confidence: 99%

A Bird's Eye View on Quantum Computing: Current and Future Trends

Branchini,

Conficconi,

Peverelli

et al. 2023

IEEE EUROCON 2023 - 20th International Conference on Smart Technologies

Self Cite

View full text Add to dashboard Cite

Quantum computing is a potentially highlydisruptive technology for several domains across the Computer Science field. However, many technological challenges still prevent the construction of a fault-tolerant and reliable quantum computer. These challenges sparked enormous interest in the scientific community, which led to the development of several independent strands of research. Consequently, research in the quantum computing domain is fragmented, making it highly specialized. This can lead to missed opportunities in identifying valuable research directions and contributions from neighboring research areas. For these reasons, this paper provides an overview of the current state of play in quantum computing for different quantum research areas at different layers of the development stack. Furthermore, for each of them, we highlight possible new outlooks that could be pivotal in the near future.

show abstract

Section: Quantum Random Access Memorymentioning

confidence: 99%

A Bird's Eye View on Quantum Computing: Current and Future Trends

Branchini,

Conficconi,

Peverelli

et al. 2023

IEEE EUROCON 2023 - 20th International Conference on Smart Technologies

Self Cite

View full text Add to dashboard Cite

show abstract

“…Many fields of biochemical research have been augmented by the application of theoretical methods in recent years, including drug design and high-throughput compound screening, − protein engineering, − and development of new fluorescent molecules and photoswitches. − As computational resources become more powerful, larger scales of simulation and analysis become possible, whether through sheer quantity of compounds, which may be investigated by a given method, or by improved accuracy and scale of analysis available for any single compound. For example, improvements in the GPU architecture combined with expanded storage capabilities allow for solvated molecular simulations to be performed at the microsecond scale rather than the nanosecond scale, and simulations, which once took months to run, can be completed in less than a week. − Machine learning has further expanded the scope of potential data sets and simulation times available. These improvements to computational capacity lead to increased demand to exploit that capacity in pursuit of a better scientific understanding of complex biochemical problems.…”

Section: Introductionmentioning

confidence: 99%

AutoParams: An Automated Web-Based Tool To Generate Force Field Parameters for Molecular Dynamics Simulations

Hix,

Walker

2023

J. Chem. Inf. Model.

View full text Add to dashboard Cite

Many research questions benefit from molecular dynamics simulations to observe the motions and conformations of molecules over time, which rely on force fields that describe sets of common molecules by category. With the increase of importance for large data sets used in machine learning and growing computational efficiency, the ability to rapidly create large numbers of force field inputs is of high importance. Unusual molecules, such as nucleotide analogues, functionalized carbohydrates, and modified amino acids, are difficult to describe consistently using standard force fields, requiring the development of custom parameters for each unique molecule. While these parameters may be created by individual users, the process can become time-consuming or may introduce errors that may not be immediately apparent.We present an open-source automated parameter generation service, AutoParams, which requires minimal input from the user and creates useful Amber force field parameter sets for most molecules, particularly those that combine molecular types (e.g., a carbohydrate functionalized with a benzene). We include hierarchical atom-typing logic that makes it straightforward to expand with additional force fields and settings, and options for creating monomers in polymers, such as functionalized amino acids. It can be straightforwardly linked to any charge generation program and currently has interfaces to Psi4, PsiRESP, and TeraChem. It is open source and is available via GitHub. It includes error checking and testing protocols to ensure the parameters will be sufficient for subsequent molecular dynamics simulations and streamlines the creation of force field databases.

show abstract