Abstract
We experimentally demonstrate the use of photonic crystal Fano resonances for reshaping optical data signals. We show that the combination of an asymmetric Fano resonance and carrier-induced nonlinear effects in a nanocavity can be used to realize a nonlinear power transfer function, which is a key functionality for optical signal regeneration, particularly for suppression of amplitude fluctuations of data signals. The experimental results are explained using simulations based on coupled-mode theory and also compared to the case of using conventional Lorentzian-shaped resonances. Using indium phosphide photonic crystal membrane structures, we demonstrate reshaping of 2 Gbit/s and 10 Gbit/s return-to-zero on-off keying (RZ-OOK) data signals at telecom wavelengths around 1550 nm. Eye diagrams of the reshaped signals show that amplitude noise fluctuations can be significantly suppressed. The reshaped signals are quantitatively analyzed using bit-error ratio (BER) measurements, which show up to 2 dB receiver sensitivity improvement at a BER of 10-9 compared to a degraded input noisy signal. Due to efficient light-matter interaction in the high-quality factor and small mode-volume photonic crystal nanocavity, low energy consumption, down to 104 fJ/bit and 41 fJ/bit for 2 Gbit/s and 10 Gbit/s, respectively, has been achieved. Device perspectives and limitations are discussed.
Highlights
Optical signal regeneration is a process that is used to clean-up a data signal which has been degraded by noise and other signal impairments [1]
We experimentally demonstrate the use of photonic crystal Fano resonances for reshaping optical data signals
We show that the combination of an asymmetric Fano resonance and carrier-induced nonlinear effects in a nanocavity can be used to realize a nonlinear power transfer function, which is a key functionality for optical signal regeneration, for suppression of amplitude fluctuations of data signals
Summary
Optical signal regeneration is a process that is used to clean-up a data signal which has been degraded by noise and other signal impairments [1]. Transfer functions closer to an ideal step functions can be obtained by cascading two or more reshaping stages at the expense of added noise [6] Each of these stages usually exhibit either of the power transfer functions shown, which are suitable for amplitude fluctuation limiting of ‘1’ bit [region (i)] and ‘0’ bit [region (ii)]. We have experimentally realized two types of Fano resonance lineshapes whose nonlinear power transfer functions are suitable for suppressing amplitude fluctuations of ‘0’ and ‘1’ bit of optical data signals. We have added a new class of applications of Fano resonances for optical signal reshaping
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