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 Test
& Measurements
Wavelength Stabilizer:
Thermally stabilized FPP-Is can be employed in a frequency control feedback loop
to stabilize laser sources within the wavelength range of 400nm to 1650nm.
Beat Frequency Noise Source: A useful
and unique high frequency measurement technique has been developed that uses a
dense comb source generated from the combination of a broadband source and a FFP-I
This technique provides a significant increase in measurement dynamic range for
high-frequency characterization of photoreceivers.[1]
Stabilization in Amplified Delayed Self-Heterodyne Interferometer:
Very high resolution linewidth measurement has been demonstrated by using an amplified
re-circulating delayed self-heterodyne interferometer. A FFP-TF is incorporated
to lock on the input signal and prevent spurious lasing. [2]
Tunable and Swept-Wavelength Source:
Swept-wavelength and tunable lasers across different spectral regions can be built
by incorporating a FFP-TF or a CTF into an active cavity. Different wavelength
ranges can be obtained by using different active media such as active fibers,
waveguides, and semiconductor optical amplifiers. Because of the high profile
purity and low-loss nature of Micron Optics tunable filters, the resulting swept
lasers can exhibit very high signal to spontaneous emission ratio (SSE) and signal
to total spontaneous emission ratio (STSE) over a wide tuning range. An incoherent,
narrowband swept source can also be configured by using a broadband source as
the input.
A wide range of applications can take advantage of
swept-wavelength lasers. These include WDM component testing (in 1.5µm for
general network components, in 1.4 µm for Raman amplifier components, in
0.98µm for pump stabilizing FBGs), remote sensing, mechanical sensing, ranging,
and bio-medical diagnostics. [3-18]
Tunable, Short-Pulse, Mode-Locked Lasers: High
quality and high repetition-rate short-pulse lasers can be promising light sources
for optical communication applications as well as numerous scientific and engineering
applications. FFP-TFs and FFP-Is have been employed in a variety of short-pulse
laser configurations to perform crucial functions such as the stabilization of
mode-locked pulses, regenerative and harmonic mode locking, and wavelength tuning.
Furthermore, FFP-TFs made of polarization-maintaining fibers have also been incorporated
into mode-locked fiber lasers for transmitter applications.
When
a section of active fiber (erbium/ytterbium co-doped fiber) is incorporated to
form a FFP laser (FFPL), it can function as a multimode source and a high-finesse
filter within a ring configuration to generate robust and stable mode-locked pulses.
Enabled by precise fabrication processes, FFP-Is and FFP-Ls can contribute to
the realization of practical and compact short pulse sources with precise repetition
rates. [19-26]
Signal
Generation By Modulation Side-Band Filtering: High-repetition-rate (10
to >100GHz) soliton pulse sources are very useful in high data-rate optical
communications. One rather efficient and cost effective technique has been demonstrated
that uses a single DFB laser source, an external phase modulator, and a FFP-TF.
Specifically, the DFB laser was phase modulated at a specific frequency, and two
optical carriers were generated by using a FFP-TF to filter out a pair of harmonic
sidebands. The beat signal from the two combined side-band carriers were then
amplified and compressed using a dispersion-shifted fiber to produce near-transform-limited
soliton pulse train. A 100GHz soliton pulse train was demonstrated to have with
very low timing jitter due to the advantage that the two sidebands share a common
frequency noise. [27]
 Microwave
Photonics
Scanning Receiver for Microwave
Signal Processing: High-resolution FFP-TFs, designed to have FSR in the
microwave frequency ranges of 10’s of GHz, and bandwidths of MHz, have been
applied in microwave scanning receiver applications. In essence, the FFP-TF can
be used to analyze microwave sidebands that have been imposed on an optical carrier
by a radio frequency (RF) signal. This approach should facilitate the removal
of bulky local oscillator and downconverter blocks from the receiver system. [28]
 Spectroscopy
Tunable filters can be fabricated for spectroscopic applications
in various spectral regions, from 400nm violet to 1.6µm IR. Application
techniques may include spectral noise filtering and signal band selection, source
stabilization and referencing, emission band detection and analysis. Application
areas include atomic emission spectroscopy, analytical chemistry, and remote atmospheric
monitoring. [29]
 Aerospace
& Lidar
Micron Optics FFP-TFs have been designed into
satellite communication platforms and structure health monitoring of aerospace
vehicles. The filters robust design has allowed full qualification in rocket launch
tests. Tunable filters and associated modules and instruments can be applied for:
- Ranging
- Atmospheric sensing
- Free-space
communication
- In-flight optical networks
- In-flight
structure health monitoring and control
 Biomedical
Micron
Optics tunable sources, filters, and spectrum analyzers can be applied in biomedical
field to analyze fluorescence spectrum, spectrally-resolved light stimulation,
optical coherence tomography, fiber-optic spectral polarimeter, and other critical
optical parameters. For articles using Micron Optics products
in biomedical applications such as optical coherence tomography, go to our Biomedical
Applications section. Defense
and Security In security applications such as perimeter
surveillance, fault detection, and ranging, fiber-optic sensing technologies are
being actively adopted. In sensing techniques incorporating optical frequency
domain reflectometry (OFDR) or fiber Bragg grating (FBG) sensors, Micron Optics
swept and tunable lasers can be applied as sensor interrogation sources.
 Micron
Optics’ swept sources and OSA instruments can be applied for biomedical
and chemical sensing of trace pollutants, toxic gases, and in vivo temperature
profiling in human bodies. It will be extremely useful to advance the optical
monitoring systems to protect transcontinental oil/gas pipelines, bridges/tunnels,
and biological contamination.
FFP-Is made with different specialty
fibers have been investigated for various sensing applications and research activities;
some examples include magnetic and electric field sensors. [30]
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