Person:
Glezer, Ari

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Publication Search Results

Now showing 1 - 10 of 12
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    Fluidic actuation and control of munition aerodynamics
    (Georgia Institute of Technology, 2009-08-31) Glezer, Ari
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    Nanojets – Formation, characterization and applications
    (Georgia Institute of Technology, 2008-12-21) Landman, Uzi ; Glezer, Ari ; Allen, Mark G. ; King, William ; Brand, Oliver ; Luedtke, William ; Gao, Jianping
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    ITR/PE+SY digital clay for shape input and display
    (Georgia Institute of Technology, 2007-11-30) Book, Wayne J. ; Rossignac, Jarek ; Mynatt, Elizabeth D. ; Allen, Mark G. ; Goldthwaite, John Randall ; Rosen, David W. ; Glezer, Ari
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    Microjet cooling devices for thermal management of electronics
    (Georgia Institute of Technology, 2003-06) Kercher, Dan S. ; Lee, Jeong-Bong ; Brand, Oliver ; Allen, Mark G. ; Glezer, Ari
    This research is an effort to demonstrate the applicability of miniaturized synthetic jet (microjet) technology to the area of thermal management of microelectronic devices. Synthetic jets are jets which are formed from entrainment and expulsion of the fluid in which they are embedded. Design issues of microjet cooling devices are discussed along with characterization of excitation elements and the turbulent synthetic jets produced thereby. Geometrical parameters of the microjet cooling devices were empirically optimized with regards to cooling performance. The cooling performance of the optimized microjets was compared with previous theoretical and empirical studies of conventional jet impingement. The cooling performance of the microjet devices has been investigated in an open environment as well as in a vented and closed case environment. In such experiments, the synthetic jet impinges normal to the surface of a packaged thermal test die, comprising a heater and a diode-based temperature sensor. This test assembly allows simultaneous heat generation and temperature sensing of the package, thereby enabling assessment of the performance of the synthetic jet. Using microjet cooling devices, a thermal resistance of 30.1 °C/W has been achieved (when unforced cooling is used, thermal resistance is 59.6 °C/W) when the test chip is located at 15 mm spacing from the jet exit plane. In order to more directly compare and scale the cooling results, a preliminary study on heat transfer correlations of the microjet cooling device has been performed. Finally, a comparison of the performance of the microjet cooler with standard cooling fans is given.
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    Finger Sculpting with Digital Clay: 3D Shape Input and Output through a Computer-Controlled Real Surface
    (Georgia Institute of Technology, 2003) Book, Wayne J. ; Glezer, Ari ; Ebert-Uphoff, Imme ; Shaw, Christopher D. ; Rossignac, Jarek ; Allen, Mark G. ; Rosen, David W. ; Askins, Stephen Alexander ; Bai, Jing ; Bosscher, Paul Michael ; Gargus, Joshua ; Kim, Byungmoon ; Llamas, Ignacio ; Nguyen, Austina Nga ; Yuan, Guang ; Zhu, Haihong
    The NSF Digital Clay project is focused on the design, prototyping, integration, and validation of a computer-controlled physical device capable of taking any of a wide range of possible shapes in response to changes in a digital 3D model or to changes in the pressure exercised upon it by human hands. Although it clearly is a natural and unavoidable evolution of 3D graphical user interfaces, its unprecedented capabilities constitute a major leap in technologies and paradigms for 3D display, for 3D input, and for collaborative 3D design. In this paper, we provide an overview of the Digital Clay project and discuss the challenges, design choices, and initial solutions for a new Finger Sculpting interface designed for the Digital Clay and prototyped using conventional 3D I/O hardware.
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    Shear flow control using synthetic jet fluidic actuator technology
    (Georgia Institute of Technology, 1999) Glezer, Ari
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    Control of natural convection along a heated, inclined plane
    (Georgia Institute of Technology, 1999) Glezer, Ari
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    Neural network determination of optical phase correction in a plane shear
    (Georgia Institute of Technology, 1998) Glezer, Ari
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    Control of particle laden jets
    (Georgia Institute of Technology, 1998) Glezer, Ari
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    Synthetic jets for thrust vector control
    (Georgia Institute of Technology, 1997-03) Glezer, Ari