Paper
2 March 2015 Akinetic swept source with adjustable coherence length for SS-OCT
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Abstract
An electronically controlled optical swept source (SS) at 1550 nm using mode locking in a dispersive ring cavity is described. Active mode-locking was achieved by directly modulating the current of a semiconductor optical amplifier (SOA) used as a gain medium. In the static regime, parameters such as linewidth, tuning bandwidth and contrast were measured, while the axial range was determined dynamically. Two types of fiber, dispersion compensation and single mode, are employed in the laser ring cavity. It is demonstrated that the relative lengths of the two types of fiber have little effect on the linewidth, while more control on the linewidth is obtained via the frequency of the signal driving the SOA. Linewidths less than 60 pm and over 1 nm were measured in the static regime while driving the SOA at 50 – 500 MHz. The narrowest linewidths were achieved where the proportion of dispersion compensation fiber in the cavity is 80- 90% of the total length. The optical source is developed to respond to the demands of OCT applications in general as well as address the need for low cost tunable lasers for configurations where a large tuning bandwidths and long coherence length might not be necessary.
© (2015) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Radu F. Stancu, David A. Jackson, and Adrian Gh. Podoleanu "Akinetic swept source with adjustable coherence length for SS-OCT", Proc. SPIE 9312, Optical Coherence Tomography and Coherence Domain Optical Methods in Biomedicine XIX, 931238 (2 March 2015); https://doi.org/10.1117/12.2077640
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KEYWORDS
Mode locking

Optical coherence tomography

Coherence (optics)

Single mode fibers

Modulation

Laser resonators

Optical isolators

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