opticalfibers in such indoor installations must tolerate numerous sharp bends,
These same fibers also can be used for medical applications [ 18 – 20 ]. These
bend-loss insensitivefibers have a moderately higher numerical aperture (NA) than
conventional single-modefibers. Increasing the NA reduces the sensitivity of the
fiber to bending loss by confining optical power more tightly within the core than in
conventional single-modefibers.
Various manufacturers offer a bend-loss insensitivefiber that has a lower
single-mode cutoff wavelength, a nominally 50 % higher index difference valueΔ,
and a 25 % higher NA than conventional telecomfibers [ 5 ]. The higher NA of
low-bend-lossfibers allows an improved coupling efficiency from laser diode
sources to planar waveguides. Generally for bend radii of greater than 20 mm, the
bending-induced loss is negligibly small. Fibers are available in which the maxi-
mum bending induced loss is less than 0.2 dB due to 100 turns on a 10-mm
mandrel. A factor to keep in mind is that at operating wavelengths in the near
infrared, the smaller modefield diameter of low-bend-lossfibers can induce a
mode-mismatch loss when interconnecting thesefibers with standard single-mode
fibers. However, carefully made splices between these differentfibers typically
results in losses less than 0.1 dB.
3.5.4 Polarization-Maintaining Fiber
In a conventional single-mode fiber the fundamental mode consists of two
orthogonal polarization modes (see Chap. 2 )[ 5 ]. These modes may be chosen
arbitrarily as the horizontal and vertical polarizations in the x direction and y
direction, respectively, as shown in Fig.3.9. In general, the electricfield of the light
xCoreyCladdingHorizontal mode sees
an effective index nxnxxCoreyCladdingVertical mode sees
an effective index nynyFig. 3.9 Two polarization states of the fundamental mode in a single-modefiber
3.5 Specialty Solid-Core Fibers 73