D. Semleit et al., FLUCTUATIONS AND NOISE OF THE OPTICAL OUTPUT POWER OF LASER-DIODES AND THE EFFECT ON OPTICAL-PARTICLE SIZE DETERMINATION, Aerosol science and technology, 26(4), 1997, pp. 356-367
Laser diodes are increasingly used as alight source in optical particl
e measurement technology. They offer the advantages of very small size
, very low weight, and have recently become commercially available wit
h a sufficient optical output power and at an acceptable price. Howeve
r, they have the disadvantages of needing a matched current source and
of having a generally higher noise level than gas lasers. In optical
particle measurement technology, the amplitude of the light scattered
by the particles is very often used to get information about the parti
cles. The scattered light intensity is directly proportional to the in
cident light intensity. So the noise of the light source directly affe
cts the quality of the scattered light, and can produce errors in the
particle size determination. This paper investigates the constancy of
the optical output power of laser diodes in combination with specific
current sources, and calls attention to possible problems in optical p
article size determination. A measurement method is introduced with ex
ample laser diodes and current sources to find the best combination of
laser diode and current source with the lowest noise level in the opt
ical output power. The optimum range of operation is determined with m
easurements. Further, the influence of the noise in the optical output
power on particle size determination is estimated theoretically with
an error propagation calculation. The measurements show a very low rms
noise in the optical power output of laser diodes. The quantitative e
stimation of the error in particle size determination shows that the e
rror below a particle diameter of 1 mu m for polystyrene lates (PSL) a
nd for laser diode wavelengths of 670 and 780 nm is insignificant. Abo
ve this particle diameter, error can increase due to the slight slope
of the scattered light curve. (C) 1997 American Association for Aeroso
l Research.