Abstract
A novel design of a tunable True-Time delay line (TTDL) based on a multicore photonic crystal fiber (PCF) is proposed. It enables simultaneous transport and processing of microwave photonic signals over a broad radiofrequency processing range. Independent group delay behavior in 19 different cores characterized by a constant differential group delay between cores provides TTDL operation on 19 signal samples. The 19-core PCF structure allows tailoring the chromatic dispersion range between 1.5 and 31.2 ps/nm·km, which translates into a very broad microwave signal processing range from a few up to tens of GHz. A near-zero dispersion slope reduces the time delay errors in the TTDL's operation to less than 5% in a 40-nm optical wavelength range, thus ensuring its satisfactory performance. Its performance as a TTDL is evaluated in terms of higher-order dispersion as well as other degradation effects such as crosstalk and nonlinear fiber response. A high index contrast between core and cladding, between 0.3 to 1.5%, enables low intercore crosstalk and confinement losses as well as greater robustness against fiber bends and twists. Fabrication of this type of MCF might be possible although it will prove challenging. This work advances the state-of-the-art of a TTDL based on SDM technology by increasing the number of samples and microwave processing range.
Highlights
T RUE time Delay Line (TTDL) is a key element in many important microwave photonic (MWP) applications such as microwave signal filtering, optical beamforming for phase-array antennas, arbitrary waveform generation and multigigabit-persecond analog-to-digital conversion, amongst others [1]
We present, for the first time to our knowledge, a multicore photonic crystal fiber (PCF) that operates as a fiber-distributed element for microwave signal processing
A TTDL based on a multicore optical fibers (MCFs) can work in two different operation regimes, space diversity and wavelength diversity, depending upon whether the TTDL samples are provided by the different fiber cores or by different input optical wavelengths, respectively [7]
Summary
T RUE time Delay Line (TTDL) is a key element in many important microwave photonic (MWP) applications such as microwave signal filtering, optical beamforming for phase-array antennas, arbitrary waveform generation and multigigabit-persecond analog-to-digital conversion, amongst others [1]. Several SDM fiber technologies have been previously proposed and demonstrated as distributed signal processing solutions, where each individual spatially multiplexed path provides a given TTDL sample. These spatial paths can either be individual homogeneous [8] or heterogeneous cores of a MCF [9], [10], or individual modes in a few-mode fiber [11].
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