Real‐world implications of high‐performance competencies and strategic management simulation technology

We address the task of classifying car images at multiple levels of detail, ranging from the top-level car type, down to the specific car make, model, and year. We analyze existing datasets for car classification, and identify the CompCars as an excellent starting point for our task. We show that convolutional neural networks achieve an accuracy above 90% on the finest-level classification task. This high performance, however, is scarcely representative of real-world situations, as it is evaluated on a biased training/test split. In this work, we revisit the CompCars dataset by first defining a new training/test split, which better represents real-world scenarios by setting a more realistic baseline at 61% accuracy on the new test set. We also propagate the existing (but limited) type-level annotation to the entire dataset, and we finally provide a car-tight bounding box for each image, automatically defined through an ad hoc car detector. To evaluate this revisited dataset, we design and implement three different approaches to car classification, two of which exploit the hierarchical nature of car annotations. Our experiments show that higher-level classification in terms of car type positively impacts classification at a finer grain, now reaching 70% accuracy. The achieved performance constitutes a baseline benchmark for future research, and our enriched set of annotations is made available for public download.

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Improving speed of models for improved real-world decision-making

10.31235/osf.io/sqy8c ◽

2021 ◽

Author(s):

Jason Thompson ◽

Haifeng Zhao ◽

Sachith Seneviratne ◽

Rohan Byrne ◽

Rajith Vidanaarachichi ◽

...

Keyword(s):

High Performance Computing ◽

Real World ◽

High Performance ◽

Time Pressure ◽

Practical Importance ◽

Model Development ◽

Sudden Onset ◽

Health Crisis ◽

Performance Improvements ◽

Performance Computing

The sudden onset of the COVID-19 global health crisis and as-sociated economic and social fall-out has highlighted the im-portance of speed in modeling emergency scenarios so that ro-bust, reliable evidence can be placed in policy and decision-makers’ hands as swiftly as possible. For computational social scientists who are building complex policy models but who lack ready access to high-performance computing facilities, such time-pressure can hinder effective engagement. Popular and ac-cessible agent-based modeling platforms such as NetLogo can be fast to develop, but slow to run when exploring broad param-eter spaces on individual workstations. However, while deploy-ment on high-performance computing (HPC) clusters can achieve marked performance improvements, transferring models from workstations to HPC clusters can also be a technically challenging and time-consuming task. In this paper we present a set of generic templates that can be used and adapted by NetLogo users who have access to HPC clusters but require ad-ditional support for deploying their models on such infrastruc-ture. We show that model run-time speed improvements of be-tween 200x and 400x over desktop machines are possible using 1) a benchmark ‘wolf-sheep predation’ model in addition to 2) an example drawn from our own work modeling the spread of COVID-19 in Victoria, Australia. We describe how a focus on improving model speed is non-trivial for model development and discuss its practical importance for improved policy and de-cision-making in the real world. We provide all associated doc-umentation in a linked git repository.

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Validity of the strategic management simulations to predict real‐world productivity

Journal of Applied Social Psychology ◽

10.1111/jasp.12771 ◽

2021 ◽

Vol 51 (12) ◽

pp. 1156-1162

Author(s):

Piers MacNaughton ◽

Anthony Cockerill

Keyword(s):

Strategic Management ◽

Real World

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Efficient Thermal Analysis of Lab-Grown Diamond Heat Spreaders

10.1115/ipack2021-73017 ◽

2021 ◽

Author(s):

Zihao Yuan ◽

Tao Zhang ◽

Jeroen Van Duren ◽

Ayse K. Coskun

Keyword(s):

Steady State ◽

Real World ◽

High Performance ◽

Silicon Layer ◽

Maximum Temperature ◽

Cooling Performance ◽

Thermal Models ◽

Heat Spreaders ◽

Transient Simulations ◽

Transient Thermal

Abstract Lab-grown diamond heat spreaders are becoming attractive solutions compared to traditional copper heat spreaders due to their high thermal conductivity, the ability to directly bond them on silicon, and allow for an ultra-thin silicon layer. Researchers have developed various thermal models and prototypes of lab-grown diamond heat spreaders to evaluate their cooling performance and heat spreading ability. The majority of existing thermal models are built using finite-element method (FEM) based simulators such as COMSOL and ANSYS. However, such commercial simulators are computationally expensive and lead to long solution times along with large memory requirements. These limitations make commercial simulators unsuitable for evaluating numerous design alternatives or runtime scenarios for real-world high-performance processors. Because of this modeling challenge, none of the existing works have evaluated the thermal behavior of lab-grown diamond heat spreaders on real-world high-performance processors running realistic application benchmarks. Recently, we have developed a parallel compact thermal simulator, PACT, that is able to carry out fast and accurate steady-state and transient thermal simulations and can be extended to support emerging integration and cooling technologies. In this paper, we use PACT to evaluate the steady-state and transient cooling performance of lab-grown diamond heat spreaders against traditional copper heat spreaders on various real-world high-performance processors (e.g., Intel i7 6950X, IBM Power9, and PicoSoC). By using PACT with architectural performance and power simulators such as Sniper and McPAT, we are able to run transient simulations with realistic benchmarks. Simulation results show that lab-grown diamond heat spreaders achieve maximum temperature and thermal gradient reductions of up to 26.73 °C and 13.75 °C when compared to traditional copper heat spreaders, respectively. The maximum steady-state and transient simulation times of PACT for the real-world high-performance chips and realistic applications used in our experiments are 259 s and 22 min, respectively.

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Exploring sensorimotor performance and user experience within a virtual reality golf putting simulator

Virtual Reality ◽

10.1007/s10055-020-00480-4 ◽

2020 ◽

Author(s):

David J. Harris ◽

Gavin Buckingham ◽

Mark R. Wilson ◽

Jack Brookes ◽

Faisal Mushtaq ◽

...

Keyword(s):

Virtual Reality ◽

Construct Validity ◽

Real World ◽

High Performance ◽

Task Demands ◽

Self Report ◽

The Real ◽

Task Load ◽

Golf Putting ◽

Effective Transfer

Abstract In light of recent advances in technology, there has been growing interest in virtual reality (VR) simulations for training purposes in a range of high-performance environments, from sport to nuclear decommissioning. For a VR simulation to elicit effective transfer of training to the real-world, it must provide a sufficient level of validity, that is, it must be representative of the real-world skill. In order to develop the most effective simulations, assessments of validity should be carried out prior to implementing simulations in training. The aim of this work was to test elements of the physical fidelity, psychological fidelity and construct validity of a VR golf putting simulation. Self-report measures of task load and presence in the simulation were taken following real and simulated golf putting to assess psychological and physical fidelity. The performance of novice and expert golfers in the simulation was also compared as an initial test of construct validity. Participants reported a high degree of presence in the simulation, and there was little difference between real and virtual putting in terms of task demands. Experts performed significantly better in the simulation than novices (p = .001, d = 1.23), and there was a significant relationship between performance on the real and virtual tasks (r = .46, p = .004). The results indicated that the simulation exhibited an acceptable degree of construct validity and psychological fidelity. However, some differences between the real and virtual tasks emerged, suggesting further validation work is required.

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Optical atomic phase reference and timing

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2016.0241 ◽

2017 ◽

Vol 375 (2099) ◽

pp. 20160241 ◽

Cited By ~ 2

Author(s):

L. Hollberg ◽

E. H. Cornell ◽

A. Abdelrahmann

Keyword(s):

Special Relativity ◽

Real World ◽

High Performance ◽

Cold Atoms ◽

Cold Atom ◽

New Physics ◽

Atomic Clocks ◽

Commercial World ◽

Commercial Applications ◽

Quantum Technology

Atomic clocks based on laser-cooled atoms have made tremendous advances in both accuracy and stability. However, advanced clocks have not found their way into widespread use because there has been little need for such high performance in real-world/commercial applications. The drive in the commercial world favours smaller, lower-power, more robust compact atomic clocks that function well in real-world non-laboratory environments. Although the high-performance atomic frequency references are useful to test Einstein's special relativity more precisely, there are not compelling scientific arguments to expect a breakdown in special relativity. On the other hand, the dynamics of gravity, evidenced by the recent spectacular results in experimental detection of gravity waves by the LIGO Scientific Collaboration, shows dramatically that there is new physics to be seen and understood in space–time science. Those systems require strain measurements at less than or equal to 10 −20 . As we discuss here, cold atom optical frequency references are still many orders of magnitude away from the frequency stability that should be achievable with narrow-linewidth quantum transitions and large numbers of very cold atoms, and they may be able to achieve levels of phase stability, Δ Φ / Φ total ≤ 10 −20 , that could make an important impact in gravity wave science. This article is part of the themed issue ‘Quantum technology for the 21st century’.

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High Performance Simulation Technology and Evaluation Scenario Management Framework

IEICE Communications Society Magazine ◽

10.1587/bplus.2009.9_60 ◽

2009 ◽

Vol 2009 (9) ◽

pp. 9_60-9_71

Author(s):

Yumi Takaki ◽

Chikara Ohta ◽

Shigeru Kaneda ◽

Mineo Takai

Keyword(s):

High Performance ◽

Simulation Technology ◽

Performance Simulation ◽

Management Framework

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Pruners: Providing reproducibility for uncovering non-deterministic errors in runs on supercomputers

The International Journal of High Performance Computing Applications ◽

10.1177/1094342019834621 ◽

2019 ◽

Vol 33 (5) ◽

pp. 777-783 ◽

Cited By ~ 1

Author(s):

Kento Sato ◽

Ignacio Laguna ◽

Gregory L Lee ◽

Martin Schulz ◽

Christopher M Chambreau ◽

...

Keyword(s):

Real World ◽

High Performance ◽

Parallel Applications ◽

Program Execution ◽

World Production ◽

Application Development ◽

Full System ◽

Scientific Simulations ◽

Large Application

Large scientific simulations must be able to achieve the full-system potential of supercomputers. When they tap into high-performance features, however, a phenomenon known as non-determinism may be introduced in their program execution, which significantly hampers application development. Pruners is a new toolset to detect and remedy non-deterministic bugs and errors in large parallel applications. To show the capabilities of Pruners for large application development, we also demonstrate their early usage on real-world production applications.

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