Title :
Design and Dynamics of Multiloop Optical Frequency Locked Loop
Author :
Alemohammad, Milad ; Yifei Li ; Herczfeld, Peter
Author_Institution :
Dept. of Electr. & Comput. Eng., Drexel Univ., Philadelphia, PA, USA
Abstract :
Next generation radar system desires frequency agile low phase noise local oscillator signal. A rapidly tunable multiloop optical frequency locked loop (OFLL) can provide such functionality. The OFLL employs a pair of electro-optic tunable microchip lasers that are heterodyned to produce a frequency agile microwave modulated optical subcarrier. A feedback through a multiloop fiber optic based microwave frequency discriminator assures low phase noise operation. This paper concerns design and optimization of stable, low phase noise OFLLs. This paper features a parametric study, followed by proof-of-concept experiments. Phase noise of -120 dBc/Hz at 10 KHz offset is achieved experimentally and conditions for obtaining a phase noise in excess of -130 dBc/Hz are discussed.
Keywords :
electro-optical devices; laser feedback; laser frequency stability; laser mode locking; laser noise; microchip lasers; microwave oscillators; microwave photonics; optical fibres; optical modulation; phase noise; electro-optic tunable microchip lasers; frequency 10 kHz; frequency agile low phase noise local oscillator signal; frequency agile microwave modulated optical subcarrier; multiloop fiber optic based microwave frequency discriminator; multiloop optical frequency locked loop design; multiloop optical frequency locked loop dynamics; next generation radar system; stable low phase noise OFLL; Delays; Optical feedback; Optical fibers; Optical filters; Optical noise; Phase noise; Fiber delay line; laser heterodyning; local oscillator distribution; microchip laser; tunable optoelectronic synthesizer;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2013.2283470
