@misc{mohr_2010_2011, title = {The 2010 CODATA Recommended Values of the Fundamental Physical Constants}, author = {Mohr, P.J. and Taylor, {B.N.} and Newell, {D.B.}}, year = {2011}, howpublished = {{(Web} Version 6.0). This database was developed by J. Baker, M. Douma, and S. Kotochigova. Available: \url{http://physics.nist.gov/constants} {[2012-07-03]} National Institute of Standards and Technology, Gaithersburg, {MD} 20899.} } @misc{rainbow_diffract_2012, title = {{Diffraction Gratings Slides --- Linear 500 line/mm}}, author = {{Rainbow Symphony, Inc.}}, year = {2012}, howpublished = {Available \url{http://www.rainbowsymphonystore.com/difgratslidl1.html}} } @misc{cone_spectra_2008, title = {File:Cones SMJ2 E.svg}, author = {\href{https://en.wikipedia.org/wiki/User:Vanessaezekowitz}{Vanessaezekowitz} on \href{http://en.wikipedia.org/}{en.wikipedia}}, year = {2008}, } @article{Stockman:93, author = {Andrew Stockman and Donald I. A. MacLeod and Nancy E. Johnson}, journal = {J. Opt. Soc. Am. A}, keywords = {}, number = {12}, pages = {2491--2521}, publisher = {OSA}, title = {Spectral sensitivities of the human cones}, volume = {10}, month = {Dec}, year = {1993}, url = {http://josaa.osa.org/abstract.cfm?URI=josaa-10-12-2491}, doi = {10.1364/JOSAA.10.002491}, abstract = {Transient chromatic adaptation produced by an abrupt change of background color permits an easier and closer approach to cone isolation than does steady-state adaptation. Using this technique, we measured middle-wave-sensitive (M-) cone spectral sensitivities in 11 normals and 2 protanopes and long-wavelength-sensitive (L-) cone spectral sensitivities in 12 normals and 4 deuteranopes. Although there is great individual variation in the adapting intensity required for effective isolation, there is little variation in the shape of the M- and L-cone spectral-sensitivity functions across subjects. At middle and long wavelengths, our mean spectral sensitivities agree extremely well with dichromatic spectral sensitivities and with the M- and L-cone fundamentals of Smith and Pokorny \[Vision Res. 15, 161 (1975)\] and of Vos and Walraven \[Vision Res. 11, 799 (1971)\], both of which are based on the CIE (Judd-revised) 2{\textdegree} color-matching functions (CMF's). But the agreement with the M-cone fundamentals of Est\'{e}vez \[Ph.D. dissertation, Amsterdam University (1979)\] and of Vos et al. \[Vision Res. 30, 936 (1990)\], which are based on the Stiles-Burch 2{\textdegree} CMF's, is poor. Using our spectral-sensitivity data, tritanopic color-matching data, and Stiles's $\pi$3, we derive new sets of cone fundamentals. The consistency of the proposed fundamentals based on either the Stiles-Burch 2{\textdegree} CMF's or the CIE 10{\textdegree} large-field CMF's with each other, with protanopic and deuteranopic spectral sensitivities, with tritanopic color-matching data, and with short-wavelength-sensitive (S-) cone spectral-sensitivity data suggests that they are to be perferred over fundamentals based on the CIE 2{\textdegree} CMF's.}, }