4,554 research outputs found
Phonon routing in integrated optomechanical cavity-waveguide systems
The mechanical properties of light have found widespread use in the
manipulation of gas-phase atoms and ions, helping create new states of matter
and realize complex quantum interactions. The field of cavity-optomechanics
strives to scale this interaction to much larger, even human-sized mechanical
objects. Going beyond the canonical Fabry-Perot cavity with a movable mirror,
here we explore a new paradigm in which multiple cavity-optomechanical elements
are wired together to form optomechanical circuits. Using a pair of
optomechanical cavities coupled together via a phonon waveguide we demonstrate
a tunable delay and filter for microwave-over-optical signal processing. In
addition, we realize a tight-binding form of mechanical coupling between
distant optomechanical cavities, leading to direct phonon exchange without
dissipation in the waveguide. These measurements indicate the feasibility of
phonon-routing based information processing in optomechanical crystal
circuitry, and further, to the possibility of realizing topological phases of
photons and phonons in optomechanical cavity lattices.Comment: 16 pages, 7 figure
An Analysis of the Achievement Gains Made By Students in Ability-Grouped Vs. Random-Grouped Classroom Units
Because of the rapid advancements being made in the field of knowledge, educators, as well as those in other fields, must periodically take inventory. Current practices, policies, and methods must be carefully scrutinized to determine if they are the most effective. The group or class method of instruction is one such area.
The current philosophy of education held in many parts of the United States today places a great deal of importance upon the individual child. Numerous programs have been inaugurated to give the individual child as much attention as possible and still be able to have a class large enough to be practical financially. This task becomes increasingly difficult when the range of abilities within each classroom is so great. It isn\u27t uncommon in the upper elementary and secondary classes to find a spread of from six to nine years difference in ability or achievement within one classroom.
Not only do we have the problem of range within the classroom, but with the increasing school population of today, classes have grown to a prohibitive size. Add these and other problems that stem from the pressures of present day society together, and even with the best possible teacher, we get only average results
Application of Kalman Filtering for PV Power Prediction in Short-Term Economic Dispatch
The aim of this thesis is to predict the short-term power production of PhotoVoltaic (PV) power plants for the economic dispatch problem with the help of Kalman filtering. The Economic Dispatch (ED) problem in power systems is known as an optimization problem in which the cost of producing energy to reliably supply consumers is minimized, hence the power production is assigned to all the generating units that are dispatchable. Because of the generation cost of renewable energy such as PV is relatively low, it is advantageous to utilize. However, these resources are intermittent. These renewable resources bring a lot of uncertainty into the power system, their power cannot be pre-specified due to their weather dependent properties and therefore it is a big challenge to include them in the ED problem.;For this reason, the work in this thesis will focus on developing a predictive model built on Kalman Filtering for the short-term PV prediction. The model first predicts the solar irradiance and temperature based on an initial guess at each time period. Then, the Kalman filter will refine the results using sensor measurements so that the final estimated outputs from this filter can be used for better prediction in the next period. The PV electric power is then calculated since it is a function of irradiance and temperature.;The proposed methodology has been illustrated using the IEEE 24-bus reliability test system. The real data from National Renewable Energy Laboratory is used in this thesis as the actual outputs that the outputs of the predicting model should get close to. Finally, the performance of the proposed approach is obtained by comparing its results with the results from an available method called the persistent prediction method
Improved Approximation Algorithms for Segment Minimization in Intensity Modulated Radiation Therapy
he segment minimization problem consists of finding the smallest set of
integer matrices that sum to a given intensity matrix, such that each summand
has only one non-zero value, and the non-zeroes in each row are consecutive.
This has direct applications in intensity-modulated radiation therapy, an
effective form of cancer treatment. We develop three approximation algorithms
for matrices with arbitrarily many rows. Our first two algorithms improve the
approximation factor from the previous best of to (roughly) and , respectively, where is
the largest entry in the intensity matrix. We illustrate the limitations of the
specific approach used to obtain these two algorithms by proving a lower bound
of on the approximation
guarantee. Our third algorithm improves the approximation factor from to , where is (roughly) the largest
difference between consecutive elements of a row of the intensity matrix.
Finally, experimentation with these algorithms shows that they perform well
with respect to the optimum and outperform other approximation algorithms on
77% of the 122 test cases we consider, which include both real world and
synthetic data.Comment: 18 page
Financial Aid, Persistence, and Degree Completion in Masters Degree Programs
This article provides an overview of the research findings from a longitudinal study conducted at a large urban university on student financial aid, persistence, and degree completion of masters degree students. The purpose of the study was to determine how the types and amounts of student financial aid, along with students\u27 demographic and academic characteristics, are related to masters degree completion. Data were analyzed for a large cohort of masters degree students over a four-year period beginning in Fall, 1985 and ending in Summer, 1989
Developmental deep dyslexia in Chinese : a case study
2002-2003 > Academic research: refereed > Publication in refereed journalVersion of RecordPublishe
Contact of Single Asperities with Varying Adhesion: Comparing Continuum Mechanics to Atomistic Simulations
Atomistic simulations are used to test the equations of continuum contact
mechanics in nanometer scale contacts. Nominally spherical tips, made by
bending crystals or cutting crystalline or amorphous solids, are pressed into a
flat, elastic substrate. The normal displacement, contact radius, stress
distribution, friction and lateral stiffness are examined as a function of load
and adhesion. The atomic scale roughness present on any tip made of discrete
atoms is shown to have profound effects on the results. Contact areas, local
stresses, and the work of adhesion change by factors of two to four, and the
friction and lateral stiffness vary by orders of magnitude. The microscopic
factors responsible for these changes are discussed. The results are also used
to test methods for analyzing experimental data with continuum theory to
determine information, such as contact area, that can not be measured directly
in nanometer scale contacts. Even when the data appear to be fit by continuum
theory, extracted quantities can differ substantially from their true values
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