Your search keyword '"Inertia (Mechanics) -- Control"' showing total 2 results

1. Water inertial reorientation: hydrogen bond strength and the angular potential

Author

Moilanen, David E., Fenn, Emily E., Lin, Yu-Shan, Skinner, J.L., Bagchi, B., and Fayer, Michael D.

Subjects

Inertia (Mechanics) -- Control, Hydrodynamics -- Research, Hydrogen bonding -- Evaluation, Harmonic motion -- Evaluation, Hydrofoil boats -- Hydrodynamics, Hydrofoil boats -- Research, Science and technology

Abstract

The short-time orientational relaxation of water is studied by ultrafast infrared pump-probe spectroscopy of the hydroxyl stretching mode (OD of dilute HOD in [H.sub.2]O). The anisotropy decay displays a sharp drop at very short times caused by inertial orientational motion, followed by a much slower decay that fully randomizes the orientation. Investigation of temperatures from 1[degrees]C to 65[degrees]C shows that the amplitude of the inertial component (extent of inertial angular displacement) depends strongly on the stretching frequency of the OD oscillator at higher temperatures, although the slow component is frequency-independent. The inertial component becomes frequency-independent at low temperatures. At high temperatures there is a correlation between the amplitude of the inertial decay and the strength of the O-D--O hydrogen bond, but at low temperatures the correlation disappears, showing that a single hydrogen bond (OD--O) is no longer a significant determinant of the inertial angular motion. It is suggested that the loss of correlation at lower temperatures is caused by the increased importance of collective effects of the extended hydrogen bonding network. By using a new harmonic cone model, the experimentally measured amplitudes of the inertial decays yield estimates of the characteristic frequencies of the intermolecular angular potential for various strengths of hydrogen bonds. The frequencies are in the range of [approximately equal to] 400 [cm.sup.-1]. A comparison with recent molecular dynamics simulations employing the simple point charge-extended water model at room temperature shows that the simulations qualitatively reflect the correlation between the inertial decay and the OD stretching frequency. ultrafast IR experiments | dynamics | motion | MD simulations | harmonic model

Published

2008

2. Back-to-back reflector antennas with reduced moment of inertia for spacecraft spinning platforms

Author

Bahadori, Keyvan and Rahmat-Samii, Yahya

Subjects

Antennas (Electronics) -- Design and construction, Remote sensing -- Equipment and supplies, Inertia (Mechanics) -- Control, Business, Computers, Electronics, Electronics and electrical industries

Abstract

A back-to-back reflector antenna system with reduced moment of inertia is proposed in order to address the demanding problem of supporting large reflector antennas on spinning platforms. The configuration provides additional potential advantages, such as reducing the spinning speed by half for a given sampling rate when both back-to-back reflectors are utilized. Geometrical parameters of the reflector are determined such that the moment of inertia of the rotating system is reduced. It is shown that these back-to-back reflectors suffer from a high cross-pol level in the asymmetrical plane due to the large feed offset angle. Two different methods are explored to alleviate the high cross-pol level problem. In the first method, a sub reflector is utilized to minimize the cross-pol level by satisfying the Mizugutchi condition. In the second method, a tri-mode matched feed horn is suggested to achieve a similar result. The suppressed cross-pol level puts forward the gravitationally balanced back-to-back reflector antenna systems as a potential candidate for future spacecraft antennas on spinning platforms. Index Terms--Matched feeds, reflector antennas, remote sensing, spinning platforms.

Published

2007