Spectral Power Distribution of Fluorescent Lamp as a Function of Correlated Color Temperature and the General Color-Rendering Index

Abstract

This paper describes a formulation by which one can obtain spectral power distributions of fluorescent lamps with any correlated color temperature T_c, and with any general color-rendering index R_a, provided that their chromaticity points lie on the daylight locus or the plankian locus.
The spectral power distribution J (λ) is constructed by a linear combination of the averaged spectral power distribution J₀ (λ) and three characteristic functions T₁ (λ), T₂ (λ) and T₃ (λ) as follows:
J(λ) =J₀(λ) +h₁T₁(λ)+h₂T₂ (λ) +pT₃ (λ)
In the equation, T₁ (λ) and T₂ (λ) are derived so that the first and the second coefficients h₁, h₂ are determined by correlated color temperature T_c, irrespective of R_a. The third coefficient p is related to both T_c and Ra. An approximated formula is derived which relates p with R_a including Tc as parameter.
The formulation is applied to derive the spectral power distributions of fluorescent lamps with T_c ranging from 3000 K to 7000 K and with R_a of 50 to 94. The computations reconstitute well the spectral power distributions of fiuorescent lamps having the pre-specified values of T_c and R_a. The mean error in R_a is 0.14.