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Micron Optics Fiber Fabry-Perot (FFP) technology offers the
advantages of best-in-class optical resolution, accuracy, filter profiles, insertion
loss, and dynamic range as well as the highest tuning resolution by using piezoelectric
technology.
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FFP-TF2
The Micron Optics FFP-TF2 design provides improved
etalon alignment for stable long-term, high reliability,
and Telcordia-qualified
performance at a more attractive
price. Several standard low-cost configurations
are
readily available for quick delivery. FFP-TF2
9000
340 nm widely tunable filter now
available with PM fiber!
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FFP-I
The
Fiber Fabry-Perot Interferometer (FFP-I) family of products is based on a fixed
interferometer design with smooth, uniformly spaced transmission peaks. The FFP-I
consists of a lensless plane Fabry-Perot interferometer with a single-mode optical
fiber waveguide between two highly reflective multilayer mirrors. |
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FFP-SI
The
fiber Fabry-Perot Scanning Interferometer is a lensless, plane Fabry-Perot interferometer
with a single-mode optical fiber waveguide between two highly reflective multilayer
mirrors that are deposited directly onto optical fibers. |
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FFP-C
The
Micron Optics controller is an electronic piezoelectric actuator driver and optical
signal processor specially designed for the FFP Tunable Filter or Scanning Interferometer.
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picoWave®
Controller
The picoWave® Controller
is designed to be used in conjunction with the thermo electric cooler (TEC) equipped
Micron Optics picoWave-Fiber Fabry-Perot Interferometer (FFP-I), where
temperature stability is critical for wavelength reference stability.
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FFP
(Fiber
Fabry-Perot) Technology Overview | |
FFP Overview
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.
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