Abstract
Microwave photonic phase shifters based on stimulated Brillouin scattering (SBS) offer tunable and broadband, optically controllable phase shifts. However, achieving a 360° phase shift requires a large amount of SBS gain which often exceeds the available gain and power handling capability of an integrated waveguide. A Radio Frequency (RF) interference technique has recently been utilized in an integrated silicon platform, which uses forward Brillouin scattering in a suspended waveguide to compensate for the lack of available Brillouin gain in standard silicon on insulator platforms. This interference scheme amplifies the phase shift at the expense of link performance. Here, we demonstrate and analytically model a 360° ultra-broadband phase shifter using backward SBS in both fiber and on-chip by combining SBS and RF interference. The phase enhancement scheme greatly reduces the required Brillouin gain and thus the required optical power. Additionally, the backward architecture reduces filter requirements as the residual pump reflections are simpler to remove compared to the pump in the forward Brillouin scattering case, where the pump co-propagates with the signal. The model provides a deeper insight into the properties of the interferometric phase enhancement scheme and predicts the potential trade-offs of an optimized system, showing reduced link loss at higher levels of Brillouin gain. The model also predicts the sensitivity to variations of the interferometric components. Using this technique, we have demonstrated a broadband phase shift over an ultra-broad bandwidth of 0.1 - 65 GHz, limited only by the bandwidth of the available components. Also, we demonstrate a phase enhancement factor of 10 over a bandwidth of 18 GHz in an integrated chalcogenide waveguide.
Highlights
M ICROWAVE photonics (MWP) has great potential in the field of Radio Frequency (RF) phase shifters, offering far superior bandwidth, electromagnetic immunity and flexible operating frequency bands compared to electrical equivalents [1], [2]
We have demonstrated an ultra-broadband phase shifter using backward stimulated Brillouin scattering spanning a bandwidth of 65 GHz in optical fiber
We have developed a theoretical model for the phase enhancement scheme which predicts the favorable link gain reduction trade-off with phase enhancement and shows a reduction in link variation with an increase in phase enhancement factor compared to the un-enhanced case
Summary
M ICROWAVE photonics (MWP) has great potential in the field of Radio Frequency (RF) phase shifters, offering far superior bandwidth, electromagnetic immunity and flexible operating frequency bands compared to electrical equivalents [1], [2]. Due to the spectrally narrow Brillouin response, it is possible to induce a phase shift on an optical signal without affecting those around it This narrowband response enables the phase shifter to operate at low RF frequencies while simultaneously amplifying the signal. The phase enhancement scheme only requires a small amount of Brillouin gain to achieve a large phase shift, so materials with other desirable properties, such as silicon, can be used even if they are not able to achieve high levels of Brillouin gain [25] To implement this phase enhancement scheme, two spectrally separated optical signals are fed into a phase modulator, so their respective sidebands are out of phase from one another. Brillouin scattering is able to induce a gain-based phase shift, whereby sweeping through the Brillouin resonance, varied phase shifts can be applied while simultaneously varying the signal amplitude. Due to the interferometric nature of the phase enhancement scheme, there is an inherent trade-off between link gain and phase enhancement factor which we will investigate
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