Search ResultsElectronic Resources
Limit Search Results
Narrowed by:
+
Publication Date: 2018
Select an Action
59 Results Found
00000000000000000000000000000000000000000000000000000000000DEFAULT
Select a list
Make this your default list.
The following items were successfully added.
There was an error while adding the following items. Please try again.
by
Bergel, D. H.
ScienceDirect http://www.sciencedirect.com/science/book/9780120899012
Format:
Excerpt:
Cardiovascular fluid dynamics Bergel, D. H.
by
Tu, Jiyuan, author.
Format:
Excerpt:
Computational fluid dynamics : a practical approach / Tu, Jiyuan, author.
by
Friedlander, Susan, 1946-
Format:
Excerpt:
Handbook of mathematical fluid dynamics / Friedlander, Susan, 1946-
by
Friedlander, Susan, 1946-
Format:
Excerpt:
Handbook of mathematical fluid dynamics / Friedlander, Susan, 1946-
by
Koshizuka, Seiichi, author.
Format:
Excerpt:
Moving particle semi-implicit method : a meshfree particle method for fluid dynamics / Koshizuka
by
Youssefi, Pouya, author.
Format:
Excerpt:
-specific computational fluid dynamics / Youssefi, Pouya, author.
by
Pagliuca, Giampaolo, author.
Format:
Excerpt:
Model reduction for flight dynamics using computational fluid dynamics / Pagliuca, Giampaolo
by
Huynh, Hung Ngoc, author.
Format:
Excerpt:
Radiation simulation for air and oxy-fuel combustion using computational fluid dynamics / Huynh
by
Jumani, Rishi, author.
Format:
Excerpt:
Computational Fluid Dynamics Simulation of Advection Dominated Flow Using a Hybrid Discontinuous
by
Chhunchha, Aakash C., author.
Format:
Excerpt:
Aerodynamic Heating Analysis of Re-entry Space Capsule Using Computational Fluid Dynamics /
by
Crose, Marquis Grant, author.
Format:
Excerpt:
Multiscale Computational Fluid Dynamics Modeling: Parallelization and Application to Design and
by
Watanabe, Keizo, author.
Format:
Excerpt:
Fluid dynamics.
by
Chhabra, Raj, author.
Format:
Excerpt:
Fluid dynamics.
by
Breit, Dominic, author.
Format:
Excerpt:
Fluid dynamics.
by
Zhou, Lixing, author.
Format:
Excerpt:
Fluid dynamics -- Mathematical models.
by
Sutton, Brielle C. 'L., author.
Format:
Excerpt:
Fluid dynamics has been used to simulate blood flow through major arteries of the human body (e
by
Hudson, Joshua, author.
Format:
Excerpt:
First we consider various inviscid equations of fluid dynamics and show that if the initial data is
by
Meyer, Laura A., author.
Format:
Excerpt:
self-sacrifice in daily life. This model consists of five fluid dimensions which continually shape and
by
Palmore, John Aaron, Jr., author.
Format:
Excerpt:
understanding of the dynamics of fuel combustion. One way of studying this combustion process is through
by
Han, Xu, author.
Format:
Excerpt:
in building blocks of Computational Fluid Dynamics (CFD) technology has made CFD an indispensable
by
Mendez Carvajal, Julio Cesar, author.
Format:
Excerpt:
Computational Fluid Dynamics (CFD) plays an important role in engineering. It allows engineers to
by
Dusane, Ajay, author.
Format:
Excerpt:
fluid dynamics of moon jellyfish. The thesis uses a linear elastic material to describe the behavior of
by
Pawlak, Robert, author.
Format:
Excerpt:
variability in a simulated LGM climate using the Geophysical Fluid Dynamics Laboratory (GFDL) coupled
by
Begum, Assma, author.
Format:
Excerpt:
the surface of the cylinder were studied using Computational Fluid Dynamics (CFD). The flow
by
Barr, Stephen M., author. (orcid)0000-0002-0450-165X
Format:
Excerpt:
for four inflow conditions ranging from cut-in to rated wind speeds. The computational fluid dynamics
by
Shellabarger, Eli R., author.
Format:
Excerpt:
A commercially available computational fluid dynamics (CFD) solver is configured and automated to
by
Haynes, Christopher A., author.
Format:
Excerpt:
pressure loading is supported with the model, but fully coupled fluid-structure interaction is not
by
Karkisaval Ganapati, Abhijith, author.
Format:
Excerpt:
including fluid-structure interaction is developed for the sensor geometry and the dynamics of the sensor
by
Rodriguez, Steven N., author.
Format:
Excerpt:
numerically as a coupled fluid-structure interaction (aeroelastic) phenomenon. The near-wake aerodynamics are
by
Glosser, Connor Adrian, author.
Format:
Excerpt:
fluid described by potential flow in the long-wavelength limit. Variations in the local surface pressure
by
Cao, Qing, author.
Format:
Excerpt:
A three-dimensional, full-scale, transient computational fluid dynamics (CFD) model was developed
by
Jalalisendi, Mohammad, author.
Format:
Excerpt:
framework which advances fundamental research in experimental fluid mechanics, structural dynamics, and
by
Sarkar, Snigdha, author.
Format:
Excerpt:
A commercial Computational Fluid Dynamics (CFD) solver, ANSYS Fluent 18.2, is used to model
by
DiGregorio, Nicholas J., author. (orcid)0000-0002-3264-9125
Format:
Excerpt:
range of 0.3 up to 16 using the computational fluid dynamics (CFD) software, VULCAN. The boundary
by
Cheung, Mancheung, author.
Format:
Excerpt:
stimulation (FES) of the lower limb (calf) muscles. However, flow dynamics depend on the viscosity of the
by
Farajidizaji, Farzad, author.
Format:
Excerpt:
industrial processes. In classical computational fluid dynamics (CFD), there are three major methods which
by
Siuliukina, Nataliia, author.
Format:
Excerpt:
Overall, this thesis investigates multiple aspects of multi-scale fluid dynamics by both developing
by
Wang, Xiao Hua.
Format:
Excerpt:
Dynamics Code (EFDC): A Powerful Tool for Coastal Environmental Management -- 4.2. Application of EFDC to
by
Heidari Pahlavian, Soroush, author.
Format:
Excerpt:
computational fluid dynamics simulation. A relatively small neural tissue motion (~150 to 300 microm) was found
by
Li, Qiaochu, author.
Format:
Excerpt:
discovered a general approach to manipulate the network dynamics by controlling the crosslink structural
by
Myers, Taylor, author.
Format:
Excerpt:
these Lagrangian particles is in turn simulated in FireFOAM (an open source computational fluid dynamics
by
Manar, Field Hogan, author.
Format:
Excerpt:
better route to intuitive understanding of the fluid dynamic origin of the forces. The experimental data
by
Vardaman, Nathan James, author.
Format:
Excerpt:
In this study, a computational fluid dynamics (CFD) model is created to mimic the mixing of the
by
Hasselblatt, Boris.
ScienceDirect https://www.sciencedirect.com/science/handbooks/1874575X/
ScienceDirect https://www.sciencedirect.com/science/publication?issn=1874575X&volume=2
ScienceDirect https://www.sciencedirect.com/science/issue/43588-2002-999989999.7998-676022
ScienceDirect https://www.sciencedirect.com/science/issue/43588-2006-999989999.7997-661538
ScienceDirect https://www.sciencedirect.com/science/book/9780444501684
ScienceDirect https://www.sciencedirect.com/science/publication?issn=1874575X&volume=2
ScienceDirect https://www.sciencedirect.com/science/issue/43588-2002-999989999.7998-676022
ScienceDirect https://www.sciencedirect.com/science/issue/43588-2006-999989999.7997-661538
ScienceDirect https://www.sciencedirect.com/science/book/9780444501684
Format:
Excerpt:
equations. Application areas include the dynamics of neural networks, fluid flows, nonlinear optics, and
by
Jackson, Brandon A., author. (orcid)0000-0002-4148-6380
Format:
Excerpt:
The first study included in this dissertation presents a computational fluid dynamics model of the
by
Urich, Matthew D., author. (orcid)0000-0001-5146-2895
Format:
Excerpt:
. Flow reversals, discrete valve switching, nonlinear adsorption effects, and complex fluid dynamics all
by
Sweeney, Matthew Ryan, author.
Format:
Excerpt:
The fluid dynamics at the impact zone of an impinging jet dictate the initial conditions for the
by
Okosun, Tyamo, author.
Format:
Excerpt:
The goal of this research is to utilize computational fluid dynamics (CFD) modeling to provide a
by
Chowdhury, Arifur Rahim, author.
Format:
Excerpt:
condition. For modeling of the system, a commercial computational fluid dynamics simulation tool, ANSYS
by
Strong, Scott A., author.
Format:
Excerpt:
the mean-field quantum dynamics of a dilute Bose gas. This theory predicts that an irrotational fluid
by
Bakhshi, Shashwat, author.
Format:
Excerpt:
15.0, a commercial Computational Fluid Dynamics (CFD) software to simulate the whirling motion of the
by
Narayanan Subramani, Deepak, author.
Format:
Excerpt:
The coastal ocean is a prime example of multiscale nonlinear fluid dynamics. Ocean fields in such
by
Alam, Mohammad Fahd Ebna, author.
Format:
Excerpt:
isolated small droplet combustion perspective employing computational fluid dynamics with comprehensive
by
Karkhanis, Nitant Vivek, author.
Format:
Excerpt:
study the flow dynamics using Computational Fluid Dynamics (CFD) which are computationally intensive and
by
Erukulla, Gautami D., author.
Format:
Excerpt:
simulations are performed, using open source Computational Fluid Dynamics (CFD) solver OpenFOAM. The
by
Sentman, Lori, author.
Format:
Excerpt:
multi-millennial scale simulations using the Geophysical Fluid Dynamics Laboratory Earth System Model
by
Glenn, Odell Lendor, Jr., author.
Format:
Excerpt:
. A thermodynamic and computational fluid dynamics analysis of this flow is presented for the purposes
by
Ismail, Fauzi.
Format:
Excerpt:
Image Velocimetry -- 5.2.4. Computational Fluid Dynamics -- 5.2.5. Nuclear Magnetic Resonance Imaging
by
Sparrow, Ephraim M.
Format:
Excerpt:
Computational Fluid Dynamics Modeling -- 1.4.3 Reduced-Order/Compact Modeling -- 2. COMPACT/REDUCED
Select an Action