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This research examines the stability of wavelength in a fiber-optic gyroscope using a semiconductor laser diode.

February 24, 2026

Navigation-Grade Laser-Driven Fiber-Optic Gyroscope

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This research examines the stability of wavelength in a fiber-optic gyroscope using a semiconductor laser diode.
Investigated the impact of a semiconductor laser diode on wavelength stability in FOGs.
Applied pulse-frequency current modulation to enhance performance.
Measured FOG angle random walk and bias instability.
Demonstrated central-wavelength stability better than 1.6 ppm.
Achieved angle random walk of 0.002°/√h.
Observed bias instability of 0.009°/h.

Resumen

The scale factor stability of a fiber-optic gyroscope (FOG) directly depends on the stability of the central wavelength of its optical source. Although broadband highly stable light sources used in high-precision FOGs provide excellent wavelength stability, they are typically bulky, which complicates the miniaturization of FOGs and FOG-based systems. This work investigates the use of a semiconductor laser diode with pulse-frequency current modulation in a navigation-grade FOG. It is shown that this approach provides superior central-wavelength stability (better than 1.6 ppm), resulting in a FOG angle random walk and bias instability of 0.002°/√h and 0.009°/h, respectively. Comparable performance can be obtained in FOGs employing broadband highly stable light sources.

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Navigation-Grade Laser-Driven Fiber-Optic Gyroscope

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