Abstract: Methods are disclosed for quantifying physical properties of gaseous, liquid or solid samples. The near-infrared absorbance spectra of a representative field of calibration samples are measured and recorded using a spectrophotometer. The absorbance spectra of the calibration samples are evaluated by a row-reduction algorithm to determine which wavelengths in the near-infrared spectrum, and associated weighting constants, are statistically correlated to the physical property being quantified. The near-infrared absorbance of actual samples is then measured at each of the correlated wavelengths, and then corrected by the corresponding weighting constants. A reference value for the physical property being quantified is then computed from the corrected measure of the absorbance of the sample at each of the correlated wavelengths.

Abstract: A method is presented for spectral reconstruction which comprises first obtaining component concentrations of a series of mixtures, which component concentrations constitute a set of reference values. The spectral value of each member of that series of mixtures is measured at a first wavelength, which spectral value possesses contribution from individual components in the mixture, whose individual contribution is unknown. The spectral values for the series of mixtures are then mathematically cross-correlated with the component concentrations in said series of mixtures, at the first wavelength, thereby obtaining the spectral contribution for said components at that first wavelength. The spectral value of each member of that series of mixtures is measured at the second wavelength, which spectral values are then cross-correlated with component concentrations in the series of mixtures thereby obtaining the spectral contribution for said components at the second wavelength.

Abstract: A device for accurately dispensing small volumes of liquids in the form of uniform droplets. The dispensing device communicates with a source of compressed air which, during start-up transience of the dispensing device, directs a jet of compressed air at the trajectory of dispensed droplets, thereby deflecting the droplets out of their normal trajectory and away from the collecting surface or container and allowing accurate dispensing.

Abstract: An atomic absorption system comprising a radiation source that emits spectral line radiation characteristic of an element to be analyzed, an analysis region open to passage of the beam of radiation from the source and in which a sample of the substance to be analyzed is atomized, source control means for alternately energizing the source at a first intensity level to provide a radiation output that has a narrow spectral line at a wavelength of an element to be detected and at a higher intensity level to provide a radiation output of broader wavelength with intensity suppression at the wavelength of the narrow spectral line, electronic transducing means for developing an electrical signal corresponding to the sensed radiation intensity of the radiation beam that passes through the analysis region, and a log ratio circuit that utilizes integrated electrical signals corresponding to the two source energization intensity levels to provide background corrected concentration information on the element of interest i