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The Fluid Dynamics program supports fundamental research toward gaining an understanding of the physics of various fluid dynamics phenomena. Proposed research should contribute to basic scientific understanding via experiments, theoretical developments, and computational discovery.

Dynamics processing featuring upward and downward compression as well as expansion. Thresholds and ratio are controlled by clicking and dragging on the visualization in the upper part of the plugin interface. The visualization shows how input levels are mapped to output levels by the dynamics processing. The current input and output levels are marked in the visualizer by a moving disc.

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Defining the transcriptional dynamics of a temporal process such as cell differentiation is challenging owing to the high variability in gene expression between individual cells. Time-series gene expression analyses of bulk cells have difficulty distinguishing early and late phases of a transcriptional cascade or identifying rare subpopulations of cells, and single-cell proteomic methods rely on a priori knowledge of key distinguishing markers. Here we describe Monocle, an unsupervised algorithm that increases the temporal resolution of transcriptome dynamics using single-cell RNA-Seq data collected at multiple time points. Applied to the differentiation of primary human myoblasts, Monocle revealed switch-like changes in expression of key regulatory factors, sequential waves of gene regulation, and expression of regulators that were not known to act in differentiation. We validated some of these predicted regulators in a loss-of function screen. Monocle can in principle be used to recover single-cell gene expression kinetics from a wide array of cellular processes, including differentiation, proliferation and oncogenic transformation.

With a human dynamics specialization in biology, you will be well-prepared to gain admittance to and succeed in a doctoral program in physical therapy or a related program. You will take undergraduate courses that follow a pre-physical therapy track, such as physiology, anatomy, chemistry, psychology and human development. This major specialization also allows you to begin your study in USD's physical therapy professional program at the Sanford School of Medicine and earn your Doctor in Physical Therapy in six years instead of seven. Students who don't choose to enroll in the USD physical therapy program can still complete a biology degree with an emphasis on humans in four years.

If you are interested in anatomy, embryology, physiology or genomics, the human dynamics specialization is a great fit for you. You'll take classes like Biostatistics, Comparative Physiology and Vertebrate Anatomy & Embryology.

The accelerated 3+3 program partnering biology and physical therapy allows students pursuing a B.S. in biology with a specialization in human dynamics to earn their Bachelor of Science and Doctor of Physical Therapy in six years rather than the traditional seven.

The GFD Program began in 1959 at the Woods Hole Oceanographic Institution with the aim of introducing a then relatively new topic in mathematical physics, geophysical fluid dynamics, to graduate students in physical sciences. It has been held each summer since and promotes an exchange of ideas among the many distinct fields that share a common interest in the nonlinear dynamics of rotating, stratified fluids.

Our mission is to create and make accessible novel data on the dynamics of the labor markets, we work with research networks and statistical agencies, developing appropriate statistics to inform policy makers, researchers, and simply people seeking knowledge. We emphasize and meet the requirements of stakeholders: users as well as providers, balancing the utility of the data with the confidentiality of the people and businesses whose activities the data describe.

Graduate students studying fire dynamics completed a hybrid S130/S190/L80 fire certification course, granting them the title of "Firefighter Type 2" and allowing them to play a larger role in the prescribed burns and experiments we conduct as part of the Fire Dynamics program. The coursework provided exposure to fire safety, fire and weather behavior, and field work.

Since its start in 1967, the GFDI has cemented its position as the gold standard in its field, producing foundational research and core theoretical paradigms that have shaped scientific thinking about fluid dynamics in far-reaching and fundamental ways. This year, as the institute celebrates its 50th anniversary, that momentum of research and discovery continues apace.

In addition, past GFDI scholars like Albert Barcilon and Louis Howard formulated theorems and conducted studies that have proved fundamental in the field and that continue to shape research of fluid dynamics throughout the global scientific community.

The GFDI hopes to continue its legacy of leading from the front with plans to become one of the first programs in the nation to offer a doctoral program in fire dynamics and develop methods to accurately predict the onset of cold air outbreaks earlier than has ever been achieved reliably.

Tyler Bolles, a senior applied mathematics major who has conducted research on the nonequilibrium dynamics of water waves, said that the resources provided by the GFDI make the institute a dream for student researchers asking big and complicated questions.

Inspired by the seabed topography off the Gulf of Mexico, Nick Moore and his colleagues at Florida State University, Tyler Bolles and Kevin Speer, sought an explanation for this discrepancy. While a number of studies have outlined some of the dynamics that could contribute to the appearance of a rogue wave, they were curious about a less-explored but powerful mechanism: underwater cliffs.

We examine the network dynamics that lead populations of individuals who initially disagree about which behaviors are virtuous to arrive at consistent, replicable consensus in their beliefs about virtuous behavior.

The Geospace Dynamics Constellation (GDC) is a strategic Living With a Star (LWS) mission that will accomplish breakthroughs in fundamental understanding of the processes that govern the dynamics of the Earth's upper atmospheric envelope that surrounds and protects the planet. This layer resides in the nearest region of geospace and is comprised of an ionized component (the ionosphere) and a neutral component (the thermosphere) that co-exist above ~80 km altitude with the peak ambient ionospheric density occurring between 200-450 km. This region is where the transition to space literally occurs: below about 100 km altitude, the atmosphere is controlled primarily by neutral fluid dynamics, while above about 200 km, the atmosphere is strongly driven by electromagnetic forcing resulting from the dynamic interaction of the solar wind with the Earth's magnetosphere. The dynamics of the upper atmosphere at any time is the result of balancing the strength of each of its drivers, with the solar wind and magnetosphere electrodynamically driving huge impulsive changes with global-scale consequences, while the lower atmosphere continuously drives the thermosphere and ionosphere with tides, planetary, and gravity waves, shaping the global changes imposed by the magnetosphere. This constant tension between fluid dynamics and electrodynamics makes the upper atmosphere an extremely important and highly compelling region of scientific exploration. Most important, GDC will provide multipoint observations of both the energy inputs and the ionosphere-thermosphere (IT) system response with sufficient spatial and temporal resolution to finally unravel the physical processes underlying the observed system-level dynamical responses.

Published by the American Mathematical Society since 1997, the purpose of this electronic-only journal is to provide a forum for mathematical work in related fields broadly described as conformal geometry and dynamics. All articles are freely available to all readers and with no publishing fees for authors.

NAMD, recipient of a 2002 Gordon Bell Award, a2012 Sidney Fernbach Award,and a 2020 Gordon Bell Prize,is a parallel molecular dynamics code designed forhigh-performance simulation of large biomolecular systems. Based onCharm++ parallel objects, NAMDscalesto hundreds of cores for typical simulations andbeyond 500,000 coresfor the largest simulations.NAMD uses the popular molecular graphics program VMDfor simulation setup and trajectory analysis, but is also file-compatiblewith AMBER, CHARMM, and X-PLOR.NAMD is distributed free of charge with source code.You can build NAMD yourself or downloadbinariesfor a wide variety of platforms.Our tutorials showyou how to use NAMD and VMD for biomolecular modeling.

The rise of mass incarceration, spanning the 1970s to the early 2000s, was characterized by continuous, unified growth in both prison and jail populations across states and counties. In contrast, the past decade has given rise to what is widely recognized as an era of reform, with prison admission rates declining by 24 percent since 2006 and jail admissions rates down 25 percent since 2008. The national declines, however, mask the new dynamics of mass incarceration.

Human systems dynamics (HSD) creates opportunities out of chaos. Our methods give you power to see patterns in complexity. You will understand your most wicked problems in new and useful ways. Most important, you will take innovative action to move past biggest challenges and toward future success.

In such a case, our Active Damping Devices provide a solution by introducing structural damping into most of the unwanted mechanical resonances. Up to 15% structural damping can be achieved, without any major redesign effort. Compared to passive dampers, the ADD are lighter and not sensitive to changes in the supporting structure dynamics.View They use our products 2351a5e196