Browsing by Subject "High performance"
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Item Development of improved ASP formulations for reactive and non-reactive crude oils(2010-12) Yang, Hyun Tae; Huh, Chun; Pope, Gary A.; Weerasooriya, UpaliThe ability to select low-cost, high-performance surfactants for a wide range of crude oils under a wide range of reservoir conditions has improved dramatically in recent years. Surfactant formulations (surfactant, co-surfactant, co-solvent, alkali, polymer, and electrolyte) were developed by using a refined phase behavior approach. Such formulations nearly always result in more than 90% oil recovery in core flood when good surfactants with good mobility control are used. The advances that have improved performance, reduced cost, increased robustness, and extended the range of reservoir conditions for these formulations are described in this work. There are thousands of possible combinations of the chemicals that could be tested for each oil and each chemical combination requires many observations over a long time period at reservoir temperature for proper evaluation. It would take too long, cost too much and in many cases not even be feasible to test all combinations. In practice the scientific understanding is used to match up the surfactant/co-surfactant/co-solvent characteristics with the oil characteristics, temperature, salinity, hardness and so forth. Synthesized and new surfactants with much larger hydrophobes and more branching than previously available were tested. New classes of co-solvents and co-surfactants with superior performance were test to improve aqueous solubility. These new developments resulted in improved ASP formulations for both oils that react with alkali to make soap and oils that do not. Many of these developments are synergistic and taken together represent a breakthrough in reducing the cost of chemical flooding and thus its commercial potential.Item High performance façades for commercial buildings(2010-05) Bader, Stefan; Lang, Werner X.; Novoselac, Atila; Moore, Steven A.; Beaman, Michael; Whitsett, DasonDue to the fact that construction, maintenance and operation of buildings consume almost 50% of the energy today, architects play a major role in the reduction of energy consumption. The building’s envelope (façades and roof) can have a significant and measurable impact. With regard to overheating and the potential lost of internal heat, transparent parts of the building envelope have a large effect on the building’s energy consumption. Modern, transparent façade systems can fulfill contemporary demands, such as energy conservation, energy production or the degree of visual contact, of sustainable buildings in order to reduce internal heating, cooling, and electrical loads. An analysis of existing shading devices and façade design leads to a comparative analysis of conventional shading devices like horizontal and vertical blinds as well as eggcrate and honeycomb shading structures in a hot-humid climate like Austin, Texas. This study helped evaluating strengths and weaknesses of each device resulting in an optimization process of conventional shading devices. Ultimately, an optimized shading structure has been developed. This project aimed to develop an advanced transparent façade system for a south-oriented commercial façade in Austin, Texas, which fulfills high standards with regard to low energy use, by limiting cooling loads and demands for artificial lighting while avoiding glare and heat losses during the cold season. The optimization has been achieved in providing full shading for a specified period of time throughout the year while providing maximized solar exposure. The shading structure consists out of an array of fixed shading components varying in size and proportion to fulfill criteria like specific views, transparency and aesthetics. The shading structure has been compared to conventional shading devices and analyzed with regard to the reduction of annual solar radiation. The improvement in design and energy consumption contributes to the variety of shading structures for building skins. It is anticipated that the solutions will help to widen the options for aesthetically pleasing, high-performance façades for commercial buildings.Item Performance and energy efficiency via an adaptive MorphCore architecture(2014-05) Khubaib; Patt, Yale N.The level of Thread-Level Parallelism (TLP), Instruction-Level Parallelism (ILP), and Memory-Level Parallelism (MLP) varies across programs and across program phases. Hence, every program requires different underlying core microarchitecture resources for high performance and/or energy efficiency. Current core microarchitectures are inefficient because they are fixed at design time and do not adapt to variable TLP, ILP, or MLP. I show that if a core microarchitecture can adapt to the variation in TLP, ILP, and MLP, significantly higher performance and/or energy efficiency can be achieved. I propose MorphCore, a low-overhead adaptive microarchitecture built from a traditional OOO core with small changes. MorphCore adapts to TLP by operating in two modes: (a) as a wide-width large-OOO-window core when TLP is low and ILP is high, and (b) as a high-performance low-energy highly-threaded in-order SMT core when TLP is high. MorphCore adapts to ILP and MLP by varying the superscalar width and the out-of-order (OOO) window size by operating in four modes: (1) as a wide-width large-OOO-window core, 2) as a wide-width medium-OOO-window core, 3) as a medium-width large-OOO-window core, and 4) as a medium-width medium-OOO-window core. My evaluation with single-thread and multi-thread benchmarks shows that when highest single-thread performance is desired, MorphCore achieves performance similar to a traditional out-of-order core. When energy efficiency is desired on single-thread programs, MorphCore reduces energy by up to 15% (on average 8%) over an out-of-order core. When high multi-thread performance is desired, MorphCore increases performance by 21% and reduces energy consumption by 20% over an out-of-order core. Thus, for multi-thread programs, MorphCore's energy efficiency is similar to highly-threaded throughput-optimized small and medium core architectures, and its performance is two-thirds of their potential.Item The Role of leadership in high performance software development teams(2011-12) Ward, John Mason; Nichols, Steven Parks, 1950-; McCann, Robert Bruce, 1948-The purpose of this research was to investigate the role of leadership in creating high performance software development teams. Of specific interest were the challenges faced by the Project Manager without a software engineering background. These challenges included management of a non-visible process, planning projects with significant uncertainty, and working with teams that don’t trust their leadership. Conclusions were drawn from the author’s experience as a software development manager facing these problems and a broad literature review of experts from the software and knowledge worker management fields. The primary conclusion was that, until the next big breakthrough, gains in software development productivity resulting from technology are limited. The only way for a group to distinguish itself as performing at the highest levels is teamwork enabled by good leadership.