The propagation of uncertainty on measurement scales that are based on poly
nomial interpolation is described. Reformulation of the interpolation in te
rms of Lagrange polynomials, which are orthogonal over the set of measured
variables, provides the key mathematical simplification. Consequently, with
many uncertainty calculations the correlation terms do not need to be carr
ied, and the effects of the various sources of uncertainty are easily visua
lized. Indeed, once a user is familiar with Lagrange interpolation, both th
e interpolation equation and the uncertainty equation can often be written
down by inspection without the need for any intermediate calculation. The m
ethod is applied to both the International Temperature Scale of 1990 (ITS-9
0) and multiwavelength radiation thermometry to highlight the advantages of
the Lagrange approach and to illustrate some of the advantages and disadva
ntages of interpolated scales. Several means of estimating the additional u
ncertainty arising from interpolation error are also discussed.