| Why
an all-fiber Fabry-Perot Tunable Filter?
Fabry-Perot filters and interferometers have provided the
highest known optical wavelength resolution for 100 years,
and are still considered seminal instruments in many branches
of science including astronomy, atomic physics, chemistry,
lasers, metrology, optics, plasma physics and spectroscopy.
These original optical configurations, developed in the
late 1800s, were constructed of bulk lenses, mirrors and
beam optics along with geared positioning stages. However,
in spite of their superior optical resolution, "old"
bulk optic, Fabry-Perot devices had two fundamental problems:
• There is no method of guiding
the light between the mirrors, which results in extreme
sensitivity to alignment,
temperature and vibration.With each bounce of the beam,
some light walks-off and is
lost. Other light generates extra cavity modes that cause
gross deviation from the ideal
mathematical theory published in 1831 by George Airy.
• There is no mechanism for moving
the mirrors the extremely small, atomic distances required
to accurately tune or
continuously scan the Fabry-Perot device.
Advantages of Micron
Optics Fiber Fabry-Perot Technology
Charles Fabry and Albert Perot coined the term etalon (a
standard of weight or measure) to describe an optical cavity
between two reflecting surfaces.Micron Optics, Inc. has
added a single segment of optical fiber within the original
Fabry-Perot etalon and developed and patented a fiber Fabry-Perot
(FFP) tunable filter. No lenses, no collimating optics,
just simply fiber and mirrors. This true fiber etalon constitutes
Micron Optics FFP Technology. All the high optical resolution
advantage of the "old", bulk optic device is preserved,
but with three critical distinctions:
• Micron Optics FFP Technology has optical fiber inside
the etalon which guides the light with each
bounce between the mirrors. The extreme alignment, temperature,
and vibration sensitivities of the "old",
bulk-optic Fabry-Perot interferometers are gone. In fact,
the alignment sensitivity of FFP technology
is no more than that of an individual single-mode optical
fiber splice or connector.
• Micron Optics FFP Technology has natural fiber connection
compatibility unlike lenses or
integrated waveguides, which encounter fundamental
connection difficulties. The FFP platform is
joining the ranks of other commercial successful all-fiber
components, including fiber couplers, Erbium-doped
fiber amplifiers (EDFAs), and fiber Bragg gratings (FBGs).
 •
Micron Optics FFP Technology is combined with the highest
resolution mechanical positioning
devices, Piezoelectric Transducers (PZTs), to
position the mirrors in Micron Optics' FFPs. PZTs are
used in atomic force microscopes to position elements to
sub-atomic dimensions. This level of mechanical
resolution ensures stable, smooth, repeatable tuning of
any FFP filter.
These three critical innovations allow
the FFPs optical response to truly follow the Airy function
from the top of its low-loss peak down to the very bottom
of its stop band, and to be smoothly and precisely controlled
over all points in between.
Why filter response is so critical
The shape of any filter response defines its performance
characteristics. The high degree to which the Micron Optics
FFP Technology follows the Airy Function theory means optical
systems can be designed to exhibit extremely low loss, predictable
cross-talk, highly accurate power measurements, high Optical
Signal to Noise Ratio (OSNR), and excellent wavelength resolution.
 Micron
Optics FFP tunable filters show distinct advantages over
competitive Fabry-Perot technology, including excellent
linearity and isolation characteristics as shown to the
right.
Micron Optics FFP Technology means
better solutions
Micron Optics FFP Technology enables the highest performance
embedded optical channel analyzer available today, monitoring
up to 400 channels in the C band alone. The high resolution,
deep dynamic range and continuous, smooth and true tuning
combine to generate superior specifications. In addition,
these specifications are valid over the entire temperature
range of 0 to 65°C.
Micron Optics FFP Technology is used in telecom systems
around the world for optical noise filtering and dynamic
channel locking. A key attribute is the extremely low insertion
loss (<1 dB) of the Micron Optics FFP filter and its
reliable locking capability. Actual field data from thousands
of filters carrying live telecom-traffic has demonstrated
extremely high reliability (<80 FITS).
Micron Optics FFP Technology enables wide dynamic range
(70dB) optical component test and
measurement systems with lightning real time scan speeds
(0.2 sec) and incredible accuracy (+/- 1pm). These instruments
will revolutionize the manufacture of passive optical components
as they have the manufacture of Micron Optics' own FFP-TFs.
The rapid tuning and locking capabilities of Micron Optics
FFP Technology enables channel selection and dropping applications
in dynamic optical networks. The high degree to which the
filters follow the Airy Function theory allows optical engineers
to accurately design single and cascaded filters for the
densest DWDM systems (down to 6 GHz channel spacing).
Micron Optics FFP Technology with its superior set of performance
characteristics can be applied to multiple diverse applications
including those above, as well as optical transport, optical
sensing and others.
可用于光学相干断层扫描技术(光学相干层析技术,Optical
Coherence Tomography)的开发。
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