Title :
Photonic Multiple Frequency Measurement Using a Frequency Shifting Recirculating Delay Line Structure
Author :
Nguyen, Tu A. ; Chan, E.H.W. ; Minasian, Robert A.
Author_Institution :
Sch. of Electr. & Inf. Eng., Inst. of Photonics & Opt. Sci., Sydney, NSW, Australia
Abstract :
A new photonic frequency measurement structure that can realise multiple-frequency measurement, while simultaneously achieving a high resolution and a wide measurement range is presented. It is based on successively frequency shifting the modulation sideband of an optical signal until it falls close to the reference carrier frequency, and then combining it with an unshifted carrier and detecting it through a narrowband filter. Experimental results demonstrate a multiple-frequency detection capability over a range of 0.1-20 GHz, which can readily be extended to 100 GHz, together with a high measurement resolution of 250 MHz and small measurement error.
Keywords :
frequency measurement; microwave photonics; optical delay lines; optical filters; optical information processing; optical modulation; optical variables measurement; frequency 0.1 GHz to 20 GHz; frequency 100 GHz; frequency 250 MHz; frequency shifting recirculating delay line structure; measurement error; measurement resolution; modulation sideband; multiple-frequency detection capability; multiple-frequency measurement; narrowband filter; optical signal; photonic frequency measurement structure; photonic multiple frequency measurement; reference carrier frequency; unshifted carrier; Amplitude modulation; Frequency measurement; Frequency modulation; Optical amplifiers; Optical filters; Optical switches; Radio frequency; Frequency measurement (FM); microwave photonics; optical signal processing;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2329488
