Title :
Light-to-input nonlinearities in an R-LED series network
Author :
Theofanous, N.G. ; Arapoyianni, A.T.
Author_Institution :
Dept. of Inf., Athens Univ., Greece
fDate :
1/1/1992 12:00:00 AM
Abstract :
The light-to-current (L-I) and light-to-voltage (L-V) differential nonlinearities in the simple network of a customary LED and an external resistor R in series are analyzed and calculated theoretically and compared with experimental data. Particular emphasis is placed on the influence of the log-arithmetic slope ν of the L-I characteristic and the bias current I upon the ratio of the corresponding nonlinearity parameters. It is thus deduced that, for a given optical power P, over superlinear portions of the L-I curve (ν>1) the L-I linearity is typically better than its corresponding L-V linearity. On the contrary, when the L-I dependence is sublinear (ν<1) the voltage driving scheme may ensure for the R-LED network, or the LED alone, a local L-V response much more linear than the L-I response, provided that appropriate (optimum) I and/or R values are chosen
Keywords :
light emitting diodes; LED; R-LED series network; bias current; differential nonlinearities; external resistor R; light emitting diodes; light-to-current; light-to-input nonlinearities; light-to-voltage; log-arithmetic slope; optical power; voltage driving scheme; Equations; Intelligent networks; Laser radar; Light emitting diodes; Linearity; Optical arrays; Optical distortion; Optical sensors; Phased arrays; Voltage;
Journal_Title :
Quantum Electronics, IEEE Journal of
