RESUMEN
Wideband signal amplification and optical signal processing with a high gain using an optical parametric amplifier based on a periodically poled LiNbO3 (PPLN) waveguide is attractive for constructing wideband optical fiber networks. We experimentally investigate the transfer characteristics of the phase noise of a pump laser in χ(2)-based optical parametric amplification and wavelength conversion on the basis of second-harmonic-generation and differential-frequency-generation processes. We also evaluate the effect of the transferred phase noise on signal quality in dispersion-unmanaged digital coherent fiber transmission systems. We show that the phase noise is transferred only to the wavelength-converted idler and does not affect the amplified signal even by using a pump laser with a MHz-order linewidth. We also show that the phase noise transferred to the idler light can have a similar impact on signal quality as equalization-enhanced phase noise (EEPN) in digital coherent transmission. The signal penalty including EEPN was evaluated with several pump lasers and at symbol rates of 32, 64, and 96 Gbaud. We also propose a method of using correlated pump lights between a wavelength converter pair to cancel out the transfer of phase noise.
RESUMEN
Phase-sensitive amplifiers (PSAs) via the optical parametric amplification (OPA) process are capable of near-noiseless amplification, which can improve the performance of optical communications systems. OPA based on periodically poled lithium niobate (PPLN) waveguides is a proven means to implement a PSA with low additional nonlinear effects, such as frequency chirp, stimulated Brillouin scattering, and parametric crosstalk due to unwanted nonlinear interactions among pump and other signal waves. However, fiber compatibility is a challenge because optical coupling loss between a fiber and PPLN waveguide limits essential performance such as the gain and noise figure (NF), which makes PSAs still far from being practical. In this work, we developed a PPLN-waveguide-based pump-combiner-integrated OPA module with fiber input and output ports. With our recent development and optimization of the OPA module, we demonstrated high-performance phase-sensitive amplification with a gain of over 30 dB and an NF of 1.0 dB. In addition, we observed a 3-dB gain bandwidth of over 65 nm and flat NF characteristics in that wavelength band. The high conversion efficiency and high damage resistance of the PPLN waveguide, obtained by employing direct bonding and dry etching techniques, provide a high parametric gain. The low-loss coupling for the signal and pump between the fiber and a spot-size-converter-integrated PPLN waveguide through the dichroic beam combiner improve not only the gain but also the NF of the amplifier. Using the PSA as a preamplifier, the low-noise characteristics were confirmed by the sensitivity improvement provided by the low NF value.
RESUMEN
We experimentally demonstrate an ultra-low-noise pre-amplification using a non-degenerate phase-sensitive amplifier (ND-PSA) with an optically dispersion-unmanaged link. Chromatic dispersion (CD) compensation is required for phase-sensitive amplification after fiber transmission. In the conventional transmitter configuration for ND-PSAs in which phase-conjugated light (idler light) is optically generated, it is necessary to optically compensate for the CD, for example, by using dispersion-compensating fibers. In this work, we propose an ND-PSA scheme using a digitally generated idler and CD pre-equalization by means of digital signal processing. We conduct an unrepeated transmission over a 200-km single-mode fiber with a 10-Gbaud 64QAM signal using the periodically poled LiNbO3-based PSA. The experimental results demonstrate that the proposed ND-PSA scheme provides a low-noise pre-amplification that outperforms the EDFA without optical CD compensation.
RESUMEN
Volume holographic demultiplexers (VHDMs) provide spatial mode demultiplexing using simple optical systems. However, applying VHDM to practical optical communication systems is difficult, as typical holographic media have no sensitivity in the infrared region, which includes optical transmission bands. In this paper, we propose a VHDM scheme combined with a dual-wavelength method (DWM). Using the DWM, VHDMs are able to perform mode demultiplexing in the optical transmission bands. We experimentally demonstrated the basic operation of our proposal using experiments performed at an 850-nm wavelength. In addition, we performed numerical simulations to investigate the application of VHDM to the C-band.
