Browsing by Author "Sykes, Patrick"
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Item Developing a chip-scale optical clock(SPIE, 2021-02-27) Zhou, Weimin; Cahill, James; Ni, Jimmy H.; Deloach, Andrew; Cho, Sang-Yeon; Anderson, Stephen; Mahmood, Tanvir; Sykes, Patrick; Sarney, Wendy L.; Leff, Asher C.We report our in-house R&D efforts of designing and developing key integrated photonic devices and technologies for a chip-scale optical oscillator and/or clock. This would provide precision sources to RF-photonic systems. It could also be the basic building block for a photonic technology to provide positioning, navigation, and timing as well as 5G networks. Recently, optical frequency comb (OFC)-based timing systems have been demonstrated for ultra-precision time transfer. Our goal is to develop a semiconductor-based, integrated photonic chip to reduce the size, weight, and power consumption, and cost of these systems. Our approach is to use a self-referenced interferometric locking circuit to provide short-term stabilization to a micro-resonator-based OFC. For long-term stabilization, we use an epsilon-near-zero (ENZ) metamaterial to design an environment-insensitive cavity/resonator, thereby enabling a chip-scale optical long-holdover clock.Item Nonlinear Interaction between a Frequency Signal and Neighboring Data Channels in a Commercial Optical Fiber Communication System(2018-01-01) Sykes, Patrick; Menyuk, Curtis R; Computer Science and Electrical Engineering; Engineering, ElectricalWe theoretically investigate the feasibility of transmitting a frequency signal in an interstice of the data channels in a commercial wavelength division multiplexed optical fiber communications system. We will give an overview of some different measures used for frequency stability. We also list the typical optical impairments that affect light propagating in an optical fiber and how the impairments can induce phase noise in a frequency signal. The phase noise on the frequency signal due to the optical impairments can be limited by restricting the optical power, bandwidth, and center frequency of the signal. The primary source of phase noise is cross-phase modulation (XPM) between the frequency signal and its neighboring data channels. We calculate the first order structure functions and Allan deviation of the phase noise resulting from XPM as the averaging time varies using typical commercial system parameters. We find that the instability added by this effect is comparable to experimentally observed instabilities in research networks, suggesting that frequency transfer over commercial networks without occupying an entire data channel should be feasible.