Indications CROSS technique

For brevity, results from selected in vitro and in vivo studies employing either near-infrared absorption spectroscopy or Raman spectroscopy, the most commonly used techniques, are documented in Tables 12.1 and 12.2. In these tables, error estimates are reported with either CV or P in parentheses, indicating cross-validated or predicted results, respectively. For an explanation of these terms, please refer to Section 12.4. 

The detection technique can also have an effect upon the angle- and velocity-dependent intensities. Cross sections refer to fluxes of molecules into a given range of velocities and angles. The connnonly employed teclmique of mass spectrometric detection provides a measure of the density in the ionization region. Since density and flux are related by the velocity, we must include a factor of 1/v hr making the transfonnation indicated in equation (B2.3.10) from the CM cross sections to tire measured laboratory intensities. 

Other techniques that work well on small computers are based on the molecules topology or indices from graph theory. These fields of mathematics classify and quantify systems of interconnected points, which correspond well to atoms and bonds between them. Indices can be defined to quantify whether the system is linear or has many cyclic groups or cross links. Properties can be empirically fitted to these indices. Topological and group theory indices are also combined with group additivity techniques or used as QSPR descriptors. 

In many respects, the Waller et al. study is an exemplary taxometric report. The authors used multiple taxometric techniques and examined the construct validity of the taxon. However, three issues were not clarified in the report. First, only base rate estimates were reported and there was no discussion about shapes of the plots, so it is unclear how many of them were taxonic. Also, only one type of consistency test—cross-method consistency— was reported in the study although the different procedures were consistent with each other, it is difficult to determine the strength of each individual piece of evidence. Second, mini-scales were used for MAXSLOPE but not for the other analyses. The authors indicated that they created mini-scales because individual items are not very reliable. However, it is unclear why this would not also have been beneficial to the MAMBAC and MAXCOV analyses. Third, nuisance correlations and indicator validities were not computed. It is thus unclear how well the data conforms to CCK requirements, and how much we can trust the estimates. Moreover, this information could have been useful in assembling the DES-T. 

The OLED is composed of hard and soft layers so that the conventional cross-sectional TEM sample preparation techniques cannot be applied. Figure 10.3 is a first DB microscopy-prepared TEM image of an OLED in cross-sectional view [37], The glass substrate, ITO, organic layers, and A1 cathode are indicated in the image. The microstructure and interfaces of all these layers can be well studied now. The nanometer-sized spots in organic layers are indium-rich particles. We believe the combination of DB microscopy and TEM will greatly advance the OLED research and development in the near future. 

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