Phase regeneration of a BPSK data signal using a Lithium Niobate phase modulator
Phase regeneration of a BPSK data signal using a Lithium Niobate phase modulator
We propose a scheme for phase regeneration of an optical binary phase shift keying (BPSK) data signal using a Lithium Niobate (LiNbO3) phase modulator. The scheme is based on heterodyne detection of the BPSK data signal with a continuous wave local oscillator (CW-LO). Carrier recovery is then achieved in the electrical domain using a x2 frequency-multiplier and a narrow-band filtering scheme. Subsequently, a superposition of the recovered carrier and the heterodyne detected data signal is used to modulate the CW-LO in a LiNbO3 phase modulator. The result is a parametric mixing process in the optical domain, leading to a phase-regenerated BPSK data signal by the coherent superposition with a phase-inverted copy. The proposed scheme constitutes a compact and stable setup, where active phase-stabilization of the electrical data- and carrier-paths can potentially be avoided. An analytical derivation of the working principle is provided, using Jacobi-Anger expansions to describe the phase-modulation. A proof-of-principle experiment is carried out, demonstrating regeneration of a 10 Gb/s NRZ-BPSK data signal degraded by a 5-GHz sinusoidal phase-noise tone. In the proof-of-principle demonstration, the decorrelated data- and LO-carriers are derived from the same CW source. A preliminary test with separate CW sources for data and LO, but without the required electrical narrow-band carrier filtering, is also included. Finally, numerical simulations of the regenerator performance in the presence of wideband phase- and amplitude-noise are performed.
differential phase-shift keying, microwave communication, Optical communication, phase regeneration
2189-2198
Mulvad, Hans Christian Hansen
b461b05f-88f2-4f28-b20a-e45cf258f456
Da Ros, Francesco
21fcf85f-0873-4dbc-b251-c3352266da0f
Galili, Michael
5628c538-e95f-417f-b008-a4c781fb6c39
Dalgaard, Kjeld
ae8fdf2f-c23b-42d8-b284-a4bcbd7bf6c8
Oxenløwe, Leif K.
1c01e3f5-29bd-4a4d-8707-ad9b76cf7462
4 March 2015
Mulvad, Hans Christian Hansen
b461b05f-88f2-4f28-b20a-e45cf258f456
Da Ros, Francesco
21fcf85f-0873-4dbc-b251-c3352266da0f
Galili, Michael
5628c538-e95f-417f-b008-a4c781fb6c39
Dalgaard, Kjeld
ae8fdf2f-c23b-42d8-b284-a4bcbd7bf6c8
Oxenløwe, Leif K.
1c01e3f5-29bd-4a4d-8707-ad9b76cf7462
Mulvad, Hans Christian Hansen, Da Ros, Francesco, Galili, Michael, Dalgaard, Kjeld and Oxenløwe, Leif K.
(2015)
Phase regeneration of a BPSK data signal using a Lithium Niobate phase modulator.
Journal of Lightwave Technology, 33 (11), , [7054432].
(doi:10.1109/JLT.2015.2408568).
Abstract
We propose a scheme for phase regeneration of an optical binary phase shift keying (BPSK) data signal using a Lithium Niobate (LiNbO3) phase modulator. The scheme is based on heterodyne detection of the BPSK data signal with a continuous wave local oscillator (CW-LO). Carrier recovery is then achieved in the electrical domain using a x2 frequency-multiplier and a narrow-band filtering scheme. Subsequently, a superposition of the recovered carrier and the heterodyne detected data signal is used to modulate the CW-LO in a LiNbO3 phase modulator. The result is a parametric mixing process in the optical domain, leading to a phase-regenerated BPSK data signal by the coherent superposition with a phase-inverted copy. The proposed scheme constitutes a compact and stable setup, where active phase-stabilization of the electrical data- and carrier-paths can potentially be avoided. An analytical derivation of the working principle is provided, using Jacobi-Anger expansions to describe the phase-modulation. A proof-of-principle experiment is carried out, demonstrating regeneration of a 10 Gb/s NRZ-BPSK data signal degraded by a 5-GHz sinusoidal phase-noise tone. In the proof-of-principle demonstration, the decorrelated data- and LO-carriers are derived from the same CW source. A preliminary test with separate CW sources for data and LO, but without the required electrical narrow-band carrier filtering, is also included. Finally, numerical simulations of the regenerator performance in the presence of wideband phase- and amplitude-noise are performed.
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Published date: 4 March 2015
Keywords:
differential phase-shift keying, microwave communication, Optical communication, phase regeneration
Identifiers
Local EPrints ID: 457587
URI: http://eprints.soton.ac.uk/id/eprint/457587
ISSN: 0733-8724
PURE UUID: 0baa782f-da8d-488d-8f5f-c7677c827dfe
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Date deposited: 13 Jun 2022 16:49
Last modified: 17 Mar 2024 03:38
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Contributors
Author:
Hans Christian Hansen Mulvad
Author:
Francesco Da Ros
Author:
Michael Galili
Author:
Kjeld Dalgaard
Author:
Leif K. Oxenløwe
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