Affiliation:
1. Radio and Optics Communication Laboratory, School of Electronic Engineering, Dublin City University, D09 V209 Dublin, Ireland
Abstract
Here, we report on a simplified laser frequency noise measurement technique employing an acousto-optic modulator, a delay line, and a real-time oscilloscope. The technique is a slight modification of the typical delayed heterodyne method. Instead of using a swept frequency spectrum to analyze the laser emission spectrum, the waveform captured on a real-time oscilloscope is used to directly calculate the laser frequency noise. The oscilloscope bandwidth and sampling requirements can be kept modest by choosing a modulator driven at a few hundred megahertz, making this technique attractive for a large number of laboratories. We show the frequency noise measurements of two different lasers with linewidths at 2.7 kHz and 2 MHz. We took the opportunity to investigate the noise floor of the frequency noise measurement system, and we found that the noise floor of the frequency noise measurement depends on the power level of the laser that is being characterized, with the kilohertz linewidths laser requiring more power to reduce the noise floor to acceptable levels.
Reference27 articles.
1. Effects of a variable linewidth laser and variable linewidth shape laser on coherent FMCW LiDAR;Zhou;Opt. Contin.,2023
2. Lee, J., Hong, J., and Park, K. (2023). Frequency Modulation Control of an FMCW LiDAR Using a Frequency-to-Voltage Converter. Sensors, 23.
3. Performance limits and laser linewidth requirements for optical PSK heterodyne communication systems;Kazovsky;IEEE J. Lightwav. Technol.,1986
4. Phase estimation methods for optical coherent detection using digital signal processing;Taylor;IEEE J. Lightwav. Technol.,2009
5. Digital Coherent Optical Receivers: Algorithms and Subsystems;Savory;IEEE J. Sel. Top. Quantum Electron.,2010