Brown-Forman Corporation and the Distilleries Industry

This study showed that Brown-Forman Corporation’s (Brown-Forman) has a winning business strategy. It passes the three major tests, which are the Fit Test, Competitive Advantage Test, and Performance Test. The company’s strategy effectively addresses the company’s situation both internally and externally. The strategy takes advantage of most of the industry’s trends, mitigates the negative impacts of the industry’s driving forces, and ensures that the company meets the industry’s key success factors. It helps the company achieve sustainable competitive advantages by fully utilizing its biggest resources and capabilities. The strategy has also directly contributed to the company’s financial success and market standing. In comparison to its biggest competitor, Beam Inc. (Beam), Brown-Forman has significantly stronger financial position within the industry. Some of its biggest financial strengths include its ability to generate cash from operations, obtain high returns from invested capital, and create strong, positive cash flows for future acquisitions and shareholder return. Areas where the company could improve include developing strategies to address changes in regulatory and political environment, developing ways to guarantee a steady supply of their products’ key inputs, and utilizing strategic partnerships for distribution. The company should also consider acquiring companies like the Firefly Distillery and Bacardi to expand their product breadth and geographic reach

A gamma ray monitor for the OSO-7 spacecraft

A 3 in. x 3 in. NaI(Tl) gamma ray (0.3 to 10 MeV) spectrometer with a CsI(Na) charged particle and anti-Compton shield has been developed for the Orbiting Solar Observatory (OSO-7) which was launched September 30, 1971. The instrument, designed for a rotating wheel compartment, utilizes a 377 channel quadratic PHA with accumulation times of 3, 1, or 0.5 minutes. Quick look and calibration data obtained via a direct data link to a minicomputer allows near real time monitoring and control of the experiment. Various commands changing the operating mode can be executed. The functions which can be commanded include: rotation of the quadrants in which data is collected by 90 deg; gain adjustment of the central detector over a 6:1 range; manual or automatic sequencing of calibrations; variations of accumulation times by telemetering selected channels; and selection of reference directions. A small X-ray detector covering the range 7.5 to 120 keV is also included

Coherence-enhanced imaging of a degenerate Bose gas

We present coherence-enhanced imaging, an in situ technique that uses Raman superradiance to probe the spatial coherence properties of an ultracold gas. Applying this method, we obtain a spatially resolved measurement of the condensate number and more generally, of the first-order spatial correlation function in a gas of $^{87}$Rb atoms. We observe the enhanced decay of propagating spin gratings in high density regions of a Bose condensate, a decay we ascribe to collective, non-linear atom-atom scattering. Further, we directly observe spatial inhomogeneities that arise generally in the course of extended sample superradiance.Comment: 4 pages, 4 figure

Documentation of the data analysis system for the gamma ray monitor aboard OSO-H

The programming system is presented which was developed to prepare the data from the gamma ray monitor on OSO-7 for scientific analysis. The detector, data, and objectives are described in detail. Programs presented include; FEEDER, PASS-1, CAL1, CAL2, PASS-3, Van Allen Belt Predict Program, Computation Center Plot Routine, and Response Function Programs

Direct, Non-Destructive Imaging of Magnetization in a Spin-1 Bose Gas

Polarization-dependent phase-contrast imaging is used to spatially resolve the magnetization of an optically trapped ultracold gas. This probe is applied to Larmor precession of degenerate and nondegenerate spin-1 $^{87}$Rb gases. Transverse magnetization of the Bose-Einstein condensate persists for the condensate lifetime, with a spatial response to magnetic field inhomogeneities consistent with a mean-field model of interactions. Rotational symmetry implies that the Larmor frequency of a spinor condensate be density-independent, and thus suitable for precise magnetometry with high spatial resolution. In comparison, the magnetization of the noncondensed gas decoheres rapidly.Comment: 4 pages, 4 figure