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Chinese Optics Letters
Vol. 14, Issue 11, 110602 (2016)

High order modulation format identification based on compressed sensing in optical fiber communication system

Bingxiang Hui¹, Xianfeng Tang¹, Na Gao¹, Wenbo Zhang², and Xiaoguang Zhang^1、*

Author Affiliations

¹State Key Laboratory of Information Photonics and Optical Communications, Beijing University of Posts and Telecommunications, Beijing 100876, China

²School of Science, Beijing University of Posts and Telecommunications, Beijing 100876, China

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DOI: 10.3788/COL201614.110602 Cite this Article Set citation alerts

Bingxiang Hui, Xianfeng Tang, Na Gao, Wenbo Zhang, Xiaoguang Zhang. High order modulation format identification based on compressed sensing in optical fiber communication system[J]. Chinese Optics Letters, 2016, 14(11): 110602 Copy Citation Text

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Abstract

We propose a method of modulation format identification based on compressed sensing using a high-order cyclic cumulant combined with a binary tree classifier. Through computing the fourth-order cyclic cumulant of the pretreated band signal, which is obtained by compressed sensing with the sampling rate much less than the Nyquist sampling value, the feature vector for classification is extracted. Simulations are carried out in the optical coherent fiber communication system with different modulation formats of multiple phase-shift keying and multiple quadrature amplitude modulation. The results indicate that this method can identify these modulation formats correctly and efficiently. Meanwhile, the proposed method is insensitive to laser phase noise and signal noise.

y = Φ x + z,

(1)

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(1 - δ_{K}) {‖ x ‖}^{2} \leq ‖ Φ x ‖ \leq (1 + δ_{K}) {‖ x ‖}^{2},

(2)

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C_{k, x} (τ_{1}, τ_{2}, \dots, τ_{k - 1}) = cum (x (t), x (t + τ_{1}), \dots x (t + τ_{k - 1})),

(3)

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x (t), x (t + τ_{1}), x (t + τ_{2}), \dots, x (t + τ_{k - 1}) .

(4)

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cum (x, y, z, w) = E (x y z w) - E (x y) E (z w) - E (x z) E (y w) - E (x w) E (y z) .

(5)

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C_{2, 0} (τ) = E {x (t) x (t + τ)},

(6)

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C_{4, 0} (τ) = E {x (t) x (t + τ_{1}) x (t + τ_{2}) x (t + τ_{3})} - C_{2, x} (τ_{1}) C_{2, x} (τ_{2} - τ_{3}) - C_{2, x} (τ_{2}) C_{2, x} (τ_{3} - τ_{1}) - C_{2, x} (τ_{3}) C_{2, x} (τ_{1} - τ_{2}) .

(7)

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C_{2, 0} = E [x^{2} (t)] = \frac{1}{N} \sum_{n = 1}^{N} {(x (t))}^{2},

(8)

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C_{2, 1} = E (x (t) x^{*} (t + τ)) = \frac{1}{N} \sum_{n = 1}^{N} {| x (t) |}^{2},

(9)

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C_{2, 0} = cum (x (t) x (t)), C_{2, 1} = cum (x (t) x^{*} (t)), C_{4, 0} = cum (x (t) x (t) x (t) x (t)) .

(10)

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C_{4, 0} = \frac{1}{N} \sum_{n = 1}^{N} {| x (t) |}^{4} - 3 C_{2, 0}^{2} .

(11)

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{〚 y 〛}^{2} = Φ {〚 x 〛}^{2},

(12)

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R_{{〚 y_{t} 〛}^{2}} = {〚 y_{t} 〛}^{2} {({〚 y_{t} 〛}^{2})}^{T} = (Φ {〚 x_{t} 〛}^{2}) {(Φ {〚 x_{t} 〛}^{2})}^{T} = Φ R_{{〚 x_{t} 〛}^{2}} Φ^{T} .

(13)

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vec (R_{{〚 y_{t} 〛}^{2}}) = (Φ \otimes Φ) vec (R_{{〚 x_{t} 〛}^{2}}),

(14)

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{〚 y_{t} 〛}^{2} = P_{{〚 y_{t} 〛}^{2}} vec (R_{{〚 y_{t} 〛}^{2}}) .

(15)

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{⟦ y_{t} ⟧}^{2} = P_{{⟦ y_{t} ⟧}^{2}} vec (R_{{⟦ y_{t} ⟧}^{2}}) = P_{{⟦ y_{t} ⟧}^{2}} (Φ \otimes Φ) vec (R_{{⟦ x_{t} ⟧}^{2}}) .

(16)

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C_{(4,0)}^{α} = F {〚 x_{t} 〛}^{4} - 3 {〚 F {〚 x_{t} 〛}^{2} 〛}^{2},

(17)

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{⟦ x_{t} ⟧}^{4} = diag (R_{{⟦ x_{t} ⟧}^{2}}) = P_{x} vec (R_{{⟦ x_{t} ⟧}^{2}}) = P_{x} vec ({⟦ x_{t} ⟧}^{2} {({⟦ x_{t} ⟧}^{2})}^{T}) .

(18)

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C_{4, 0} = F P_{x} vec (R_{{⟦ x_{t} ⟧}^{2}}) - 3 P_{F x} vec (R_{F {⟦ x_{t} ⟧}^{2}}) = F P_{x} vec (R_{{⟦ x_{t} ⟧}^{2}}) - 3 P_{F x} vec (F R_{{⟦ x_{t} ⟧}^{2}} F^{T}) = [F P_{x} - 2 P_{F x} (F \otimes F)] vec (R_{{⟦ x_{t} ⟧}^{2}}) .

(19)

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{⟦ y_{t} ⟧}^{2} = P_{{⟦ y_{t} ⟧}^{2}} (Φ \otimes Φ) vec (R_{{⟦ x_{t} ⟧}^{2}}) = P_{{⟦ y_{t} ⟧}^{2}} (Φ \otimes Φ) {[F P_{x} - 2 P_{F x} (F \otimes F)]}^{†} C_{4, 0} .

(20)

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Γ = Θ C_{(4, 0)}^{α},

(21)

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C_{4, 0} < 0.15 \Rightarrow 8 PSK, 0.15 \leq C_{4, 0} < 0.34 \Rightarrow 32 QAM, 0.34 \leq C_{4, 0} < 0.8 \Rightarrow 16 QAM, 0.8 \leq C_{4, 0} < 1.4 \Rightarrow QPSK, 1.4 \leq C_{4, 0} \Rightarrow BPSK,

(22)

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References (17)

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Bingxiang Hui, Xianfeng Tang, Na Gao, Wenbo Zhang, Xiaoguang Zhang. High order modulation format identification based on compressed sensing in optical fiber communication system[J]. Chinese Optics Letters, 2016, 14(11): 110602

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