Power efficient communications employing phase sensitive pre-amplified receiver
Power efficient communications employing phase sensitive pre-amplified receiver
The receiver sensitivity is a very important metric in optical communication links operating at low received signal powers. Phase sensitive optical amplifiers (PSAs) can amplify optical signals without excess noise, thus providing a fundamental sensitivity improvement of 3 dB when employed as a pre-amplifier compared to conventional erbium doped fiber amplifiers (EDFA). In this letter, we investigate, both theoretically and experimentally, the sensitivities achieved using power efficient multi-dimensional modulation formats such as M-ary pulse position modulation format (M-PPM) and M-PPM combined with quadrature phase shift keying (QPSK) along with a near-noiseless PSA pre-amplified coherent intradyne receiver. We find that at high signal to noise ratios (SNRs) corresponding to low bit-error-rates (BER), M-PPM+QPSK results in the best sensitivity, which is improved with the order M, while at low SNRs corresponding to high BER (14% where 100% overhead forward error correction codes (FEC) would be needed to recover the data), QPSK is the most sensitive format, while at the same time providing the best spectral efficiency. We report experimental sensitivities of 2.1 photons per information bit (PPB) at a pre-FEC BER = 10-3 using 64-PPM+QPSK and assuming 7% FEC, and 0.8 PPB at a pre-FEC BER = 0.14 using QPSK and assuming 100% FEC.
Bit error-rate, modulation format, phase sensitive amplifier, pulse position modulation, receiver sensitivity
3-6
Kakarla, Ravikiran
6508a016-64d6-42d0-8739-c88315cccbfe
Mazur, Mikael
2d43bf2b-09a5-45b4-824e-09c89d1351ea
Schröder, Jochen
bb1bee59-7961-4a12-977a-4f719e24506b
Andrekson, Peter A.
a51e01b3-654a-4fd3-a8bd-8a5587b6f449
1 January 2022
Kakarla, Ravikiran
6508a016-64d6-42d0-8739-c88315cccbfe
Mazur, Mikael
2d43bf2b-09a5-45b4-824e-09c89d1351ea
Schröder, Jochen
bb1bee59-7961-4a12-977a-4f719e24506b
Andrekson, Peter A.
a51e01b3-654a-4fd3-a8bd-8a5587b6f449
Kakarla, Ravikiran, Mazur, Mikael, Schröder, Jochen and Andrekson, Peter A.
(2022)
Power efficient communications employing phase sensitive pre-amplified receiver.
IEEE Photonics Technology Letters, 34 (1), .
(doi:10.1109/LPT.2021.3130430).
Abstract
The receiver sensitivity is a very important metric in optical communication links operating at low received signal powers. Phase sensitive optical amplifiers (PSAs) can amplify optical signals without excess noise, thus providing a fundamental sensitivity improvement of 3 dB when employed as a pre-amplifier compared to conventional erbium doped fiber amplifiers (EDFA). In this letter, we investigate, both theoretically and experimentally, the sensitivities achieved using power efficient multi-dimensional modulation formats such as M-ary pulse position modulation format (M-PPM) and M-PPM combined with quadrature phase shift keying (QPSK) along with a near-noiseless PSA pre-amplified coherent intradyne receiver. We find that at high signal to noise ratios (SNRs) corresponding to low bit-error-rates (BER), M-PPM+QPSK results in the best sensitivity, which is improved with the order M, while at low SNRs corresponding to high BER (14% where 100% overhead forward error correction codes (FEC) would be needed to recover the data), QPSK is the most sensitive format, while at the same time providing the best spectral efficiency. We report experimental sensitivities of 2.1 photons per information bit (PPB) at a pre-FEC BER = 10-3 using 64-PPM+QPSK and assuming 7% FEC, and 0.8 PPB at a pre-FEC BER = 0.14 using QPSK and assuming 100% FEC.
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More information
e-pub ahead of print date: 1 January 2022
Published date: 1 January 2022
Keywords:
Bit error-rate, modulation format, phase sensitive amplifier, pulse position modulation, receiver sensitivity
Identifiers
Local EPrints ID: 471088
URI: http://eprints.soton.ac.uk/id/eprint/471088
ISSN: 1041-1135
PURE UUID: cf2717c8-ebef-443b-b8ea-e2535c68a954
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Date deposited: 25 Oct 2022 16:43
Last modified: 16 Mar 2024 22:31
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Contributors
Author:
Ravikiran Kakarla
Author:
Mikael Mazur
Author:
Jochen Schröder
Author:
Peter A. Andrekson
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