Curve Fitting, Confidence Intervals and Envelopes, Correlations, and Monte Carlo Visualizations for Multilinear Problems in Chemistry: A General Spreadsheet Approach

• Paul Ogren ^[1] ; Brian Davis ^[1] ; Nick Guy ^[1]
  1. [1] Earlham College

     Earlham College

     Township of Wayne, Estados Unidos

     
• Localización: Journal of chemical education, ISSN 0021-9584, Vol. 78, Nº 6, 2001, pág. 827
• Idioma: inglés
• Texto completo no disponible (Saber más ...)
• Resumen

  • A spreadsheet approach is used to fit multilinear functions with three adjustable parameters: ƒ = a1X1(x) + a2X2(x) + a3X3(x). Results are illustrated for three familiar examples: IR analysis of gaseous DCl, the electronic/vibrational spectrum of gaseous I2, and van Deemter plots of chromatographic data. These cases are simple enough for students in upper-level physical or advanced analytical courses to write and modify their own spreadsheets. In addition to the original x, y, and σy values, 12 columns are required: three for Xn(xi) values, six for Xn(xi)Xk(xi) product sums for the curvature matrix [α], and three for yi Xn(xi) sums for (b) in the vector equation (b) = [α](a). The Excel spreadsheet MINVERSE function provides the [ε] error matrix from [α]. The [ε] elements are then used to determine best-fit parameter values contained in (a). These spreadsheets also use a "dimensionless" or "reduced parameter" approach in calculating parameter weights, uncertainties, and correlations. Students can later enter data sets and fit parameters into a larger spreadsheet that uses Monte Carlo techniques to produce two-dimensional scatter plots. These correspond to Δχ2 ellipsoidal cross-sections or projections and provide visual depictions of parameter uncertainties and correlations. The Monte Carlo results can also be used to estimate confidence envelopes for fitting plots.