Advent Of Supercomputers Research Articles

Artificial intelligence and automation in valvular heart diseases.

Artificial intelligence (AI) is gradually changing every aspect of social life, and healthcare is no exception. The clinical procedures that were supposed to, and could previously only be handled by human experts can now be carried out by machines in a more accurate and efficient way. The coming era of big data and the advent of supercomputers provides great opportunities to the development of AI technology for the enhancement of diagnosis and clinical decision-making. This review provides an introduction to AI and highlights its applications in the clinical flow of diagnosing and treating valvular heart diseases (VHDs). More specifically, this review first introduces some key concepts and subareas in AI. Secondly, it discusses the application of AI in heart sound auscultation and medical image analysis for assistance in diagnosing VHDs. Thirdly, it introduces using AI algorithms to identify risk factors and predict mortality of cardiac surgery. This review also describes the state-of-the-art autonomous surgical robots and their roles in cardiac surgery and intervention.

Latest trends in structure based drug design with protein targets.

Structure based drug designing is an important endeavor in the field of structural bioinformatics. Previously the entire process was dependent on the wet-lab experiments to build libraries of ligand molecules. And the molecules used to be tested to determine their binding efficacies with protein target. However, the entire process is very lengthy and above all highly expensive. With the advent of supercomputers and increasing computational powers, the search process for finding suitable ligand molecules against target proteins have become more streamlined and cost-effective. Now the entire ligand search process is performed in-silico with the help of the techniques of virtual screening, molecular docking simulations and molecular dynamics studies. In the present chapter, a brief overview of the computational techniques involved in structure based drug designing is presented with a special emphasis on the thermodynamic principles behind the molecular interactions.

Numerical simulation of fractured-vuggy porous media based on gamblets

Numerical simulation of a fractured-vuggy porous medium is a challenging problem. One reason is the coexistence of matrix, fractures and vugs on multiple scales that need to be coupled, and the other reason is that the high-resolution fractured-vuggy model may contain up to several millions of gridcells in applications, which brings severe computational challenges into the numerical methods. Therefore, the requirement for accurate and efficient technique is widely increasing. Fractured-vuggy porous medium is generally represented by triple-continuum model in which the matrix system, fracture system and vug system each are treated as a parallel continuous system. Although triple-continuum model is widely used because of its easy-implementation and high efficiency, it fails to capture the detailed flow patterns of reservoir with disconnected long fractures. Discrete fracture-vug network (DFVN) model can precisely model the fluid flow in fractures and vugs. However, the simulation of this model is deemed intractable even with the advent of supercomputers because of the large amount of calculation. In view of the fact that the multigrid method is now well known as one of the fastest method of solving elliptic problems, in this paper we introduce a nearly linear complexity multiresolution decomposition method for fluid flow in a fractured-vuggy reservoir. The detailed flow patterns are described by combing the advantages of continuum model and discrete model. That is, the homogenization theory is used to construct an equivalent permeability in each coarse grid block in which the vugs and small-scale fractures are represented by discrete fracture-vug network model. We decompose the solution space into several subspaces and then we compute the corresponding solutions of heterogeneous discrete fracture network model in each subspace. Gamblets are constructed and they are elementary solutions of hierarchical information games associated with the process of computing with partial information and limited resources. These gamblets have a natural Bayesian interpretation under the mixed strategy emerging from the game theoretic formulation. This method could realize its fast simulation by decomposing the solution space into a direct sum of linear subspaces that are orthogonal to each other. Finally, the pressure difference distribution of fractured-vuggy porous medium is obtained by combing the DFVN solutions of all subspaces. Numerical results are presented to demonstrate the accuracy and efficiency of the proposed multiresolution decomposition method. The results show that this method is a promising method of numerically simulating the fractured-vuggy porous medium.

Symmetries and their importance for statistical turbulence theory

The special importance of turbulence maybe comprehended by its ubiquity in innumerable natural and technical systems. Examples for natural turbulent flows are the atmospheric flow and the oceanic current which to calculate is a crucial point in climate research. Classical engineering application involving turbulence are the flows around airplanes or cars or turbulence within jet or reciprocating engines. Though supposed for more than hundred years, only with the advent of super computers it became apparent that the Navier-Stokes equations provide an excellent continuummechanical model for turbulent flows. Still, the exclusive and direct application of the Navier-Stokes equations to practical flow problems at very high Reynolds numbers without invoking any additional assumptions is still several decades away. However, in most applications it is not at all necessary to know all the detailed fluctuations of velocity and pressure present in turbulent flows but for the most part statistical measures are sufficient. This was in fact the key idea of O. Reynolds who was the first to suggest a statistical description of turbulence. The Navier-Stokes equations, however, constitute a non-linear and, due to the pressure Poisson equation, a non-local set of equations. As an immediate consequence of this the equations for the mean or expectation values for velocity and pressure lead to an infinite set of statistical equations, or, if truncated at some level of statistics, an un-closed system is generated.

Physics as Final Opportunity to Prevent Harms Related to Theatricalization of Meteorology

Using Mbane Biouele formula derived in 2009 on the troposphere thermoelastic properties leads to thermal and kinematic profiles of major atmospheric disturbances which clearly indicate that these terrible events for men should not be viewed with fatalism. This unexpected truth is unfortunately always obscured by media outlets of brilliant TV presenters or famous workshops panelists that focus attention on the excessively sensational meteorology (unfortunately folk and pernicious) instead of worrying about the seriousness that should characterize all interventions on the climate study or prediction. Good weather conditions, it is undeniable, facilitate an excellent running of almost all human activities like sports, transport, agricultural activities, celebrations of events, etc.... Far more serious, the advent of supercomputers and satellites could, if their valuable information is used solely for the theatricalization of weather events, trigger the decline of the scientific discipline of great public utility that is meteorology. Indeed, many meteorologists acquire very big head when they succeed in acquiring advanced equipment. Without prejudging what meteorology will become in the future, we hope that the work done in this article will remind each researchers that much remains to be done to promote climate studies. We remind quite emphatically that both hurricanes and cyclones have their weak-points (or talon d’Achilles in French) and thus, researchers should begin to think about “how to neutralize atmospheric disturbances that have both a large and a strong destructive power”.

Open Quantum Dynamics Calculations with the Hierarchy Equations of Motion on Parallel Computers.

Calculating the evolution of an open quantum system, i.e., a system in contact with a thermal environment, has presented a theoretical and computational challenge for many years. With the advent of supercomputers containing large amounts of memory and many processors, the computational challenge posed by the previously intractable theoretical models can now be addressed. The hierarchy equations of motion present one such model and offer a powerful method that remained under-utilized so far due to its considerable computational expense. By exploiting concurrent processing on parallel computers the hierarchy equations of motion can be applied to biological-scale systems. Herein we introduce the quantum dynamics software PHI, that solves the hierarchical equations of motion. We describe the integrator employed by PHI and demonstrate PHI's scaling and efficiency running on large parallel computers by applying the software to the calculation of inter-complex excitation transfer between the light harvesting complexes 1 and 2 of purple photosynthetic bacteria, a 50 pigment system.

Towards modeling and integrated design automation of supercomputing clusters (MIDAS)

The choice of supercomputers, by the user community, should not merely be based on the benchmarks. With the advent of supercomputers delivering petaops performance, computationally intensive applications such as brain modeling and energy requirement prediction have become predominant. Conventional benchmarks do not reflect the functional characteristics of these applications. Thus, the gap between the performance projected and the actual performance delivered when the application is ported onto the cluster is wide. The primary cause for this disparity in performance is due to the user community’s lack of knowledge about the system and improper design choices. With the supercomputer market being seller biased this problem is worsened. Design and development of very large systems like the clusters involve massive efforts and financial investment. Creating a design automation environment for the clusters is bound to bring down the man years and hence the production cost. Currently there are adhoc approaches which lack an integrated design space to cater to the wider needs of the user community. Thus, an integrated design framework that takes all the components of the supercomputing cluster and the relationship across the design spaces is essential. In this paper we propose a novel methodology called the Modeling and Integrated Design Automation of Supercomputing Cluster (MIDAS). MIDAS is the birth of a new design philosophy which requires lot of research and tuning, providing scope for evolution and optimization.

A geometry independent near-wall Reynolds-stress closure

Models proposed for high-Reynolds-number Reynolds–stress closures are, in general, geometry independent. Therefore, they are most suitable for flows with complex geometries. With the advent of supercomputers, the near-wall flow can be calculated with greater efficiency to give more accurate results on surface properties. However, with modifications made to the various models to account for near-wall behavior, the closures are no longer geometry independent. The cause is the presence of wall distance and wall unit normals in the proposed corrections for either the velocity–pressure-gradient correlation tensor, the dissipation rate tensor, the dissipation rate equation, or all of them. In this paper, a proposal is put forward where the modifications made to these tensors and equation are free of wall distance and wall unit normals. The closure is validated against a wide variety of simple flows and good agreement with data is obtained. Further, the closure is applied to calculate backstep flows and developing square duct flows. The results are compared with direct numerical simulation and experimental data. In addition, they are also compared with the calculations of another near-wall Reynolds–stress closure with wall unit normal dependence and is known to give good correlations with backstep flow and square duct flow data. The present closure is found to yield results that are in good agreement with the data and the calculations of the model with wall unit normals. As a result, a viable geometry independent near-wall Reynolds–stress closure is available.

Massively Parallel Self-Consistent-Field Calculations

The advent of supercomputers with many computational nodes each with its own independent memory makes possible very fast computations. Our work is focused on the development of electronic structure techniques for the solution of Grand Challenge-size molecules containing hundreds of atoms. Our efforts have resulted in a scalable direct-SCF (self-consistent-field) Fock matrix construction kernel that is portable and efficient. Good parallel performance is obtained by allowing asynchronous communications and using a distributed data model. These requirements are easily handled by using the Global Array (GA) software library developed for this project. This algorithm has been incorporated into the new program NWChem.

Simulations of Nanometer-Thick Lubricating Films

Hydrodynamics and elastohydrodynamics have been successful in describing lubrication by micron-thick films. However, these continuum theories begin to break down as film thicknesses become comparable to molecular dimensions. An increasing number of applications require an understanding of lubricants in such severely confined geometries. Examples include lubrication of nanoscale bearings in micromachinery or high-density magnetic disk drives, as well as asperity interactions in macroscopic bearings that operate in the mixed lubrication regime.Development of new experimental and theoretical techniques for studying thin lubricant films has paralleled the growing interest in their properties. The surface force apparatus (SFA) allows normal and shear forces to be measured between atomically flat solid surfaces while their separation is determined to within 0.1 nm using interferometry or capacitance. The contact area in the SFA is typically 100 μm across, much larger than the separation between solid walls. The atomic force microscope (AFM) can be used to explore friction in lubricated contacts whose diameter is comparable to the separation (5 nm). This allows spatial resolution of the frictional force on a molecular scale. Quartz-crystal oscillators have been used to determine the frictional forces between a surface and an adsorbed film of one or more monolayers. Theoretical advances have been aided by the advent of supercomputers that allow thin films to be simulated at the molecular level using molecular dynamics. These new experimental and theoretical techniques reveal a sequence of dramatic changes in the static and dynamic properties of fluid films as their thickness approaches molecular scales.

Teaching molecular biophysics at the graduate level

Molecular biophysicists use the concepts and tools of chemistry and molecular physics to define and analyze the structures, energetics, dynamics, and interactions of biological molecules. The recent explosion of new knowledge, methods, and needs for biophysical insight has made the development ofgraduate training programs much more challenging than was previously the case. 25 years ago, the question was What to teach? Today, the question is can everything that must be taught be packed into a reasonable amount oftime? At the same time, the recent influx of relatively large cadres of gifted, excited students; increasing resources, and the gradual shakedown and consolidation of the field combine to make the task more rewarding and in some ways more straightforward. Although graduate programs in Molecular Biophysics have existed since at least the mid1960's, the recent establishment of a Molecular Biophysics Training Program by the Institute ofGeneral Medical Sciences ofNIH has generated new interest. Molecular biophysicists are now much less likely to define themselves primarily as chemists or biochemists, or to disguise courses in molecular biophysics as courses in physical chemistry for biologists. Teaching molecular biophysics at the graduate level is difficult for the same reasons that research in the area is difficult. The potential range ofthe subject is as broad as chemistry itself, while the need to apply chemical concepts and techniques to large, complicated, strongly interacting molecules in solution and in partially ordered membrane phases pushes the state of the art in the sciences to its limits. Developments such as the theory of the helix-coil transition in double-strandedDNA, saturation-transfer EPR spectroscopy to study dynamics of membrane and muscle, and molecular dynamics simulation ofprotein dynamics, are among the most ambitious and innovative in chemistry in the last several decades. To achieve such advances requires deep, fundamental training in statistical mechanics, spin quantum mechanics, and similar areas. We cannot help worrying whether our students (who must spend considerable time learning about the biochemistry of proteins and nucleic acids, and about molecular genetics) are being trained to be innovators as well as informed users of sophisticated science. The comparison with their fellow students in molecular biology, who after a few courses dive into laboratory work that leads to ready publication, is not an easy one. Molecular biophysics has undergone a revolution in the past several decades. When the authors ofthis article were students, in the 1950's and 60's, the idea that one might obtain atomic-level structures of proteins and nucleic acids was little more than a dream. A few heroic scientists struggled for decades to get crystal structures of a few proteins, succeeding at best in tracing the chain backbone and observing some ofthe basic structural features (helices and sheets) predicted by Pauling. The prediction that we would someday accumulate structures at the rate of one per week, at a level of resolution that would enable determination of arrangement of catalytic groups in an enzyme, and subtle rearrangements upon binding of ligands, seemed beyond belief. That we would be getting similar quality of information on small proteins and oligonucleotides in solution from NMR would have seemed even more unlikely. NMR had only recently been developed as a chemical tool for small organic molecules, and the enhancements that have made it feasible for macromolecules (particularly high field superconducting magnets and Fourier transform methods) were not yet conceived. The advent of supercomputers, powerful desktop workstations, and personal computers, enabling rapid analysis of huge data sets and simulation ofmacromolecular dynamics, was unanticipated. Lasers were not yet invented. The exquisite sensitivity ofmicrocalorimeters was yet to be developed. The list of new technology and theory on which modem molecular biophysics depends could be extended almost indefinitely. Our graduate curricula were crowded enough before these modern developments, with courses in thermodynamics, quantum mechanics, statistical mechanics, and mathematics, and with perhaps a course or two in (mainly metabolic) biochemistry. How can we ask our students to take the even more sophisticated chemistry courses they need today, along with the much greater amount ofequally necessary biochemistry, genetics, and cell biology, and still have them graduate with a good thesis in five years? Frankly, we fear that we often do not do an adequate job: students in biochemistry departments don't take enough advanced chemistry and physics, and students in chemistry and physics departments don't take enough biology, to meet the challenges of current and future research in molecular biophysics. At best, they become experts in a specialized area, and learn more by reading and self study throughout their careers (as most of us older scientists have done). But it is open to question whether today's students trained as molecular biophysicists can realistically achieve the breadth and depth of knowledge needed to progress in the future as we have in the past. Perhaps it is

The beginnings of resonant ultrasound spectroscopy and its applications to geophysics

It is no accident that resonant ultrasound spectroscopy (RUS) work is deeply connected to geophysics problems. A great triumph of geophysics in the past two decades has been the inversion of the measured resonant vibration modes of the oscillating Earth as a whole, resulting from a major earthquake, to find the density distribution with depth. Over the last 20 years the fundamental theory has been extended by a series of steps to include nonspherical shapes (parallelepipeds, cones, ellipsoids, and right circular cylinders) and also materials of lower symmetry (including cubic down to monoclinic). The advent of supercomputers with their large computation capacity has made all of this possible. The benefits of applying resonant ultrasound spectroscopy to geophysical problems are also benefits to materials science, since the geophysical approach is almost identical to a good materials science approach. In this paper, some results are presented of using RUS to find solutions to some outstanding geophysical problems mainly related to high temperature applications. The materials science applications of the work are found when one emphasizes measurements of insulators of low crystal symmetry at high temperatures (up to 1800 K). This is, of course, the special domain of high-temperature ceramics. A large portion of this paper is devoted to a historical review of RUS.

Large‐scale computer simulation of fully developed turbulent channel flow with heat transfer

AbstractRecently, with the advent of supercomputers, there has been considerable interest in the use of direct numerical simulation to obtain information about turbulent shear flow at low Reynolds number. This paper presents a pseudospectral technique to solve the full three‐dimensional time‐dependent Navier‐Stokes and advection‐diffusion equations without the use of subgrid‐scale modelling. The technique has not been previously used for fully developed turbulent channel flow simulation and is based on methods applied in other contexts. The emphasis of this paper is to provide a reasonably detailed account of how the simulation is done rather than to present new calculations of turbulence. The details of an algorithm for turbulent channel flow simulation and the grid and time step sizes needed to integrate through transient behaviour to steady state turbulence have not been published before and are presented here.Results from a Cray‐2 simulation of fully developed turbulent flow in a channel with heat transfer are presented along with a critical comparison between experiment and computation. The first‐ and second‐order moments agree well with experimental measurements; the agreement is poor for higher‐order moments such as the skewness and flatness near the walls of the channel. Detailed information given about the effects of spatial grid resolution on a computed results is important for estimating the size of the computation required to study various aspects of a turbulent flow.

Stability Analysis and Improvement of the Block Gram–Schmidt Algorithm

The advent of supercomputers with hierarchical memory systems has imposed the use of block algorithms for the linear algebra algorithms. Although block algorithms may result in impressive improvements in performance, their numerical properties are quite different from their scalar counterpart and deserve an in-depth study. In this paper, the numerical stability of block Gram–Schmidt orthogonalization is studied and a variant is proposed which has numerical properties similar to the modified Gram–Schmidt procedure while retaining most of the performance advantages of the block formulation.

Nonlinear Galerkin methods: The finite elements case

With the increase in the computing power and the advent of supercomputers, the approximation of evolution equations on large intervals of time is emerging as a new type of numerical problem. In this article we consider the approximation of evolution equations on large intervals of time when the space discretization is accomplished by finite elements. The algorithm that we propose, called the nonlinear Galerkin method, stems from the theory of dynamical systems and amounts to some approximation of the attractor in the discrete (finite elements) space. Essential here is the utilization of incremental unknown which is accomplished in finite elements by using hierarchical bases. Beside a detailed description of the algorithm, the article includes some technical results on finite elements spaces, and a full study of the stability and convergence of the method.

Development of global coupled ocean-atmosphere general circulation models

It has long been believed that a climate model capable of realistically simulating many features of global climate, variability, and climate change must interactively represent the major components of the dynamically coupled climate system, particularly the atmosphere, ocean, and cryosphere. This effort traditionally has been constrained by computing power, our understanding of the observed system, and climate modeling capability. With the advent of supercomputers, improved understanding of global climate processes, and computationally efficient general circulation climate models, we have witnessed a rapid increase in the simulation of global climate by coupling together various representations of atmosphere, ocean, and sea ice. Beginning in the late 1960s and continuing through the early 1980s, general circulation models (GCMs) of the atmosphere, ocean, and sea ice were coupled and run asynchronously to produce credible simulations of the global climate. Systematic errors in these component models later led some modeling groups to use flux correction or flux adjustment, whereby either one or several of the variables at the air-sea interface are adjusted to bring the simulations in closer agreement with observations. Further advances in computing power and climate modeling techniques in the past few years have allowed global coupled ocean-atmosphere GCMs to be run synchronously (i.e., atmosphere and ocean communicate at least once each model day). Computing constraints, combined with the need for multidecadal climate integrations, still only allow relatively coarse-grid ocean GCMs to be coupled to correspondingly coarse-grid atmospheric models (on the order of 500 km × 500 km). However, results from this current generation of global, coupled GCMs have revealed interesting characteristics associated with ocean dynamics and global climate in experiments with gradual increases of carbon dioxide. Another somewhat surprising aspect of the global-coupled GCM simulations is the appearance of some features associated with the El Nino-Southern Oscillation. Along with concurrent efforts with other types of limited-domain, dynamical coupled models, this has led to the realization that inherent unstable coupled modes exist in the climate system that are the unique product of the interactive coupling of the atmosphere and the ocean. All of these efforts are leading to the next generation of coupled ocean-atmosphere GCMs. These models will run on even faster and larger-memory computers and will have higher-resolution atmosphere and ocean components, more accurate sea-ice formulations, improved cloud-radiation schemes, and increasingly realistic land-surface processes.

The use of supercomputers for the variational calculation of ro-vibrationally excited states of floppy molecules

The advent of supercomputers has led to great advances in electronic structure calculations and to the ab initio calculation of molecular spectra. Recent theoretical developments have allowed us to develop a two-step variational algorithm for the calculation of rotationally highly excited states of floppy molecules. This algorithm allows highly accurate nuclear motion calculations to be performed on low-lying ro-vibrational states and greatly extends the range of states that can practicably be considered. The algorithm has been adapted to run efficiently on the Cray supercomputers. Analysis of the timings suggest that construction of the secular matrix is highly vectorised and that the special structure of secular matrix can be used to give rapid diagonalisation. The limiting factor on these calculations is the available fast storage, but analysis suggests that this bottleneck could be removed by use of a Solid State Device (SSD). Sample results are given for calculations involving a range of rotational excitation. An adaptation of the algorithm to a loop of parallel processors is also suggested.

Development of a finite difference model for arbitrary axisymmetric acoustic pulses applicable in investigating finite ground impedance effects

With the advent of supercomputers, accurate modeling of sound propagation over a finite impedance ground via finite difference (FD) techniques is becoming possible. In this preliminary investigation, FD solutions to the fundamental hyperbolic partial differential equations governing acoustics which agree with analytic solutions are sought. The particular numerical techniques are similar to those of computational compressible fluid flow, modified for spherical waves in a cylindrical coordinate system to correctly model boundary conditions. Results for acoustic simple sources will be provided.

Solution of surface water flow equations using Clebsch variables

Conventionally, the flow equations for surface waters are obtained by integrating vertically the basic continuum conservation equations governing three‐dimensional motion, thus reducing the problem to two dimensions. However, when vertical transport is important, this model fails, and the basic equations for three‐dimensional motion must be solved directly. With the advent of super computers and attached array processors this has become feasible. In this paper a formulation based on so‐called Clebsch variables is presented. This formulation is basically equivalent to a formulation based on the vorticity. However, the formulation based on Clebsch variables does not exhibit the disadvantages of the formulation based on the vorticity. Since in the Clebsch representation an explicit expression for the pressure is available (generalized Bernoulli equation), this formulation may be considered as an extension of the well‐known potential theory for irrotational flow. A groundwater reservoir simulator solving for the pressure, temperature, and concentration can, in principle, be applied to determine the Clebsch variables describing flow in surface water, thus unifying the mathematical description of surface and subsurface hydrology. The conclusion is that a computer program based on a formulation with Clebsch variables is quite competitive, especially for three‐dimensional calculations where it should lead to a more economical use of the computer.