Ultrahigh-speed all-optical half adder based on four-wave mixing in semiconductor optical amplifier

Li Pei-li; Huang De-xiu; Zhang Xin-liang; Zhu Guang-xi

doi:10.1364/OE.14.011839

Ultrahigh-speed all-optical half adder based on four-wave mixing in semiconductor optical amplifier

Li Pei-li, Huang De-xiu, Zhang Xin-liang, and Zhu Guang-xi

Optics Express
Vol. 14,
Issue 24,
pp. 11839-11847
(2006)
•https://doi.org/10.1364/OE.14.011839

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Li Pei-li, Huang De-xiu, Zhang Xin-liang, and Zhu Guang-xi, "Ultrahigh-speed all-optical half adder based on four-wave mixing in semiconductor optical amplifier," Opt. Express 14, 11839-11847 (2006)

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Related Topics
Table of Contents Category
- Optoelectronics
Optics & Photonics Topics
?

The topics in this list come from the OSA Optics and Photonics Topics applied to this article.
Previously assigned OCIS codes
- Nonlinear optics, four-wave mixing (190.4380)
- Logic-based optical processing (200.3760)
- Semiconductor optical amplifiers (250.5980)

About this Article
History
- Original Manuscript: September 20, 2006
- Revised Manuscript: October 30, 2006
- Manuscript Accepted: October 31, 2006
- Published: November 27, 2006

Accessible

Open Access

Abstract

A novel scheme for an ultrahigh-speed all-optical half adder based on four-wave mixing (FWM) in semiconductor optical amplifiers (SOAs) is proposed. This scheme is free of pattern effect, due to using the polarization-shift-keying (PolSK) modulation format. By numerical simulation, the output power level of logic “1” dependence on the operating conditions, such as two input signal powers, injection current, and input signal wavelength, are investigated in detail using the broad-band model of this all-optical half adder.

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References

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|
Year
|
Author
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Publication

H. J. S. Dorren, X. Yang, A.K. Mishra, Z. Li, H. Ju, H. de Waardt, G.-D. Khoe, T. Simoyama, H. Ishikawa, H. Kawashima, and T. Hasama, “All-optical logic based on ultrafast gain and index dynamics in a semiconductor optical amplifier,” IEEE J. Select. Topics in Quantum Electron. 10, 1079–1092 (2004).
[Crossref]
A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]
J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]
S. H. Kim, J. H. Kim, J. W. Choi, C. W. Son, S. H. Ok, Y. T. Byun, Y. M. Jhon, S. Lee, D. Ha Woo, and S. H. Kim, “All-optical half adder using single mechanism of XGM in semiconductor optical amplifiers,” in Semiconductor Lasers and Applications IIJ. Yao, Y. J. Chen, and S. Lee, eds., Proc. SPIE5628, 94–101 (2005).
[Crossref]
D. Tsiokos, E. Kehayas, K. Vyrsokinos, T. Houbavlis, L. Stampoulidis, G. T. Kanellos, N. Pleros, G. Guekos, and H. Avramopoulos. “10-Gb/s all-optical half-adder with interferometric SOA gates,” IEEE Photon. Technol. Lett. 16, 284–286 (2004).
[Crossref]
S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).
Z. Li and G. Li, “Ultrahigh-speed reconfigurable logic gates based on four-wave mixing in a semiconductor optical amplifier,” IEEE Photon. Technol. Lett. 18, 1341–1343 (2006).
[Crossref]
M. M. Matalgah and R. M. Radaydeh, “Hybrid frequency-polarization shift-keying modulation for optical transmission,” J. Lightwave Technol. 23, 1152–1163 (2005).
[Crossref]
R. Calvani, R. Caponi, and F. Cisternino, “Polarization phase-shift keying: A coherent transmission technique with differential Heterodyne detection,” Electron. Lett. 24, 642–643 (1988).
[Crossref]
S. Benedetto, R. Gaudino, and P. Poggiolini, “Performance of coherent optical polarization shift keying modulation in the presence of phase noise,” IEEE Trans. Commun. 43, 1603–1612 (1995).
[Crossref]
S. Benedetto and P. Poggiolini, “Theory of polarization shift keying modulation,” IEEE Trans. Commun. 40, 708–721 (1992).
[Crossref]
N. C. Kothari and Daniel J. Blumenthal, “Influence of gain saturation, gain asymmetry, and pump/probe depletion on wavelength conversion efficiency of FWM in semiconductor optical amplifiers,” IEEE J. Quantum Electron. 32, 1810–1816 (1996).
[Crossref]
H. Simos, A. Bogris, and D. Syvridis, “Investigation of a 2R all-optical regenerator based on four-wave mixing in a semiconductor optical amplifier,” J. Lightwave Technol. 22, 595–604 (2004).
[Crossref]
B. Mikkelson, “Optical amplifier and their system applications,” Ph.D dissertation, Denmark Univ. Technol.163–164 (1994).
G. Talli and M. J. Adams, “Amplified spontaneous emission in semiconductor optical amplifiers: modeling and experiments,” Opt. Commun. 218, 161–166 (2003).
[Crossref]
P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

2007 (1)

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

2006 (1)

Z. Li and G. Li, “Ultrahigh-speed reconfigurable logic gates based on four-wave mixing in a semiconductor optical amplifier,” IEEE Photon. Technol. Lett. 18, 1341–1343 (2006).
[Crossref]

2005 (1)

M. M. Matalgah and R. M. Radaydeh, “Hybrid frequency-polarization shift-keying modulation for optical transmission,” J. Lightwave Technol. 23, 1152–1163 (2005).
[Crossref]

2004 (4)

H. J. S. Dorren, X. Yang, A.K. Mishra, Z. Li, H. Ju, H. de Waardt, G.-D. Khoe, T. Simoyama, H. Ishikawa, H. Kawashima, and T. Hasama, “All-optical logic based on ultrafast gain and index dynamics in a semiconductor optical amplifier,” IEEE J. Select. Topics in Quantum Electron. 10, 1079–1092 (2004).
[Crossref]

D. Tsiokos, E. Kehayas, K. Vyrsokinos, T. Houbavlis, L. Stampoulidis, G. T. Kanellos, N. Pleros, G. Guekos, and H. Avramopoulos. “10-Gb/s all-optical half-adder with interferometric SOA gates,” IEEE Photon. Technol. Lett. 16, 284–286 (2004).
[Crossref]

S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).

H. Simos, A. Bogris, and D. Syvridis, “Investigation of a 2R all-optical regenerator based on four-wave mixing in a semiconductor optical amplifier,” J. Lightwave Technol. 22, 595–604 (2004).
[Crossref]

2003 (2)

G. Talli and M. J. Adams, “Amplified spontaneous emission in semiconductor optical amplifiers: modeling and experiments,” Opt. Commun. 218, 161–166 (2003).
[Crossref]

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

1998 (1)

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

1996 (1)

N. C. Kothari and Daniel J. Blumenthal, “Influence of gain saturation, gain asymmetry, and pump/probe depletion on wavelength conversion efficiency of FWM in semiconductor optical amplifiers,” IEEE J. Quantum Electron. 32, 1810–1816 (1996).
[Crossref]

1995 (1)

S. Benedetto, R. Gaudino, and P. Poggiolini, “Performance of coherent optical polarization shift keying modulation in the presence of phase noise,” IEEE Trans. Commun. 43, 1603–1612 (1995).
[Crossref]

1992 (1)

S. Benedetto and P. Poggiolini, “Theory of polarization shift keying modulation,” IEEE Trans. Commun. 40, 708–721 (1992).
[Crossref]

1988 (1)

R. Calvani, R. Caponi, and F. Cisternino, “Polarization phase-shift keying: A coherent transmission technique with differential Heterodyne detection,” Electron. Lett. 24, 642–643 (1988).
[Crossref]

Adams, M. J.

G. Talli and M. J. Adams, “Amplified spontaneous emission in semiconductor optical amplifiers: modeling and experiments,” Opt. Commun. 218, 161–166 (2003).
[Crossref]

Avramopoulos, H.

Benedetto, S.

S. Benedetto and P. Poggiolini, “Theory of polarization shift keying modulation,” IEEE Trans. Commun. 40, 708–721 (1992).
[Crossref]

Blow, K. J.

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

Blumenthal, Daniel J.

Bogris, A.

Byun, Y. T.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

S. H. Kim, J. H. Kim, J. W. Choi, C. W. Son, S. H. Ok, Y. T. Byun, Y. M. Jhon, S. Lee, D. Ha Woo, and S. H. Kim, “All-optical half adder using single mechanism of XGM in semiconductor optical amplifiers,” in Semiconductor Lasers and Applications IIJ. Yao, Y. J. Chen, and S. Lee, eds., Proc. SPIE5628, 94–101 (2005).
[Crossref]

Calvani, R.

Caponi, R.

Choi, J. W.

Cisternino, F.

de Waardt, H.

Dorren, H. J. S.

ee, S. L.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

Gaudino, R.

Guekos, G.

Gurkan, D.

S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).

Ha Woo, D.

Hasama, T.

Houbavlis, T.

Huang, D. X.

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

Ishikawa, H.

Jhon, Y. M.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

Ju, H.

Kanellos, G. T.

Kawashima, H.

Kehayas, E.

Kelly, A. E.

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

Khoe, G.-D.

Kim, J. H.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

Kim, S. H.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

Kothari, N. C.

Kumar, S.

S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).

Lee, S.

Li, G.

Z. Li and G. Li, “Ultrahigh-speed reconfigurable logic gates based on four-wave mixing in a semiconductor optical amplifier,” IEEE Photon. Technol. Lett. 18, 1341–1343 (2006).
[Crossref]

Li, P. L.

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

Li, Z.

Z. Li and G. Li, “Ultrahigh-speed reconfigurable logic gates based on four-wave mixing in a semiconductor optical amplifier,” IEEE Photon. Technol. Lett. 18, 1341–1343 (2006).
[Crossref]

Manning, R. J.

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

Matalgah, M. M.

M. M. Matalgah and R. M. Radaydeh, “Hybrid frequency-polarization shift-keying modulation for optical transmission,” J. Lightwave Technol. 23, 1152–1163 (2005).
[Crossref]

Mikkelson, B.

B. Mikkelson, “Optical amplifier and their system applications,” Ph.D dissertation, Denmark Univ. Technol.163–164 (1994).

Mishra, A.K.

Ok, S. H.

Pleros, N.

Poggiolini, P.

S. Benedetto and P. Poggiolini, “Theory of polarization shift keying modulation,” IEEE Trans. Commun. 40, 708–721 (1992).
[Crossref]

Poustie, A. J.

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

Radaydeh, R. M.

M. M. Matalgah and R. M. Radaydeh, “Hybrid frequency-polarization shift-keying modulation for optical transmission,” J. Lightwave Technol. 23, 1152–1163 (2005).
[Crossref]

Simos, H.

Simoyama, T.

Son, C. W.

Stampoulidis, L.

Syvridis, D.

Talli, G.

G. Talli and M. J. Adams, “Amplified spontaneous emission in semiconductor optical amplifiers: modeling and experiments,” Opt. Commun. 218, 161–166 (2003).
[Crossref]

Tsiokos, D.

Vyrsokinos, K.

Willner, A. E.

S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).

Woo, D. H.

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

Yang, X.

Zhang, X. L.

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

Zhu, G. X.

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

Acta Physica Sinica (1)

P. L. Li, D. X. Huang, X. L. Zhang, and G. X. Zhu, “Novel all-optical AND and NOR Gates based on semiconductor fiber ring laser,” Acta Physica Sinica, 56, (2007) (to be published).

Electron. Lett. (1)

IEEE J. Quantum Electron. (1)

IEEE J. Select. Topics in Quantum Electron. (1)

IEEE Photon. Technol. Lett. (2)

Z. Li and G. Li, “Ultrahigh-speed reconfigurable logic gates based on four-wave mixing in a semiconductor optical amplifier,” IEEE Photon. Technol. Lett. 18, 1341–1343 (2006).
[Crossref]

IEEE Trans. Commun. (2)

S. Benedetto and P. Poggiolini, “Theory of polarization shift keying modulation,” IEEE Trans. Commun. 40, 708–721 (1992).
[Crossref]

J. Lightwave Technol. (2)

M. M. Matalgah and R. M. Radaydeh, “Hybrid frequency-polarization shift-keying modulation for optical transmission,” J. Lightwave Technol. 23, 1152–1163 (2005).
[Crossref]

OFC 2004 (1)

S. Kumar, D. Gurkan, and A. E. Willner, “All-optical half adder using a PPLN waveguide and an SOA,” OFC 2004, 1, 23–27 (2004).

Opt. Commun. (3)

A. J. Poustie, K. J. Blow, A. E. Kelly, and R. J. Manning, “All-optical binary half-adder,” Opt. Commun. 156, 22–26 (1998).
[Crossref]

J. H. Kim, Y. T. Byun, Y. M. Jhon, S. L. ee, D. H. Woo, and S. H. Kim, “All-optical half adder using semiconductor optical amplifier based devices,” Opt. Commun., 218, 345–349 (2003).
[Crossref]

G. Talli and M. J. Adams, “Amplified spontaneous emission in semiconductor optical amplifiers: modeling and experiments,” Opt. Commun. 218, 161–166 (2003).
[Crossref]

Other (2)

B. Mikkelson, “Optical amplifier and their system applications,” Ph.D dissertation, Denmark Univ. Technol.163–164 (1994).

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Fig. 1. The basic logic diagram of the half adder

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Fig. 2. Schematic diagram of the all-optical half adder

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Fig. 3. Intensity waveform for (a) the input signal 1, (b) the input signal 2, (c) the logic AND output, and (d) the logic XOR output.

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Fig. 4. Output power level of logic “1” of AND gate and XOR gate for different powers of the input signal 2

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Fig. 5. Output power level of logic “1” of AND gate and XOR gate for different input signal 1 powers

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Fig. 6. Output power level of logic “1” of AND gate and XOR gate as a function of injection current

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Fig. 7. Output power level of logic “1” of AND gate and XOR gate as a function of input signal 2 wavelength

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Tables (2)

Table 1. Truth Table of Half Adder

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Table 2 Parameter used in simulation

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Equations (13)

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\frac{d A_{s 1, i}}{d z} = \frac{1}{2} [\frac{Γ_{g_{s 1, i}}}{1 + \frac{P_{i}}{P_{s}}} (1 - i α_{i}) - α_{l}] A_{s 1, i} - \frac{{Γ g}_{s 1, i}}{2 (1 + \frac{P_{i}}{P_{s}})} (η_{s 1, s 2} {∣ A_{s 2, i} ∣}^{2} + η_{s 1, c} {∣ A_{c, i} ∣}^{2} + η_{s 1, sat} {∣ A_{sat, i} ∣}^{2}) A_{s 1, i}

- \frac{{Γ g}_{s 1, i}}{2 (1 + \frac{P_{i}}{P_{s}})} [(η_{s 2, s 1} + η_{c, s 1}) A_{s 2, i} A_{c, i} {A_{s 1, i}}^{*} + η_{s 2, sat} {A_{s 2, i}}^{2} {A_{sat, i}}^{*}]

\frac{d A_{s 2, i}}{d z} = \frac{1}{2} [\frac{Γ_{g_{s 2, i}}}{1 + \frac{P_{i}}{P_{s}}} (1 - i α_{i}) - α_{l}] A_{s 2, i} - \frac{{Γ g}_{s 2, i}}{2 (1 + \frac{P_{i}}{P_{s}})} (η_{s 2, s 1} {∣ A_{s 1, i} ∣}^{2} + η_{s 2, c} {∣ A_{c, i} ∣}^{2} + η_{s 2, sat} {∣ A_{sat, i} ∣}^{2}) A_{s 2, i}

- \frac{{Γ g}_{s 2, i}}{2 (1 + \frac{P_{i}}{P_{s}})} [(η_{s 1, s 2} + η_{sat, s 2}) A_{s 1, i} A_{sat, i} {A_{s 2, i}}^{*} + η_{s 1, c} {A_{s 1, i}}^{2} {A_{c, i}}^{*}]

\frac{d A_{c, i}}{d z} = \frac{1}{2} [\frac{Γ_{g_{c, i}}}{1 + \frac{P_{i}}{P_{s}}} (1 - i α_{i}) - α_{l}] A_{c, i} - \frac{{Γ g}_{c, i}}{2 (1 + \frac{P_{i}}{P_{s}})} (η_{c, s 1} {∣ A_{s 1, i} ∣}^{2} + η_{c, s 2} {∣ A_{s 2, i} ∣}^{2} + η_{c, sat} {∣ A_{sat, i} ∣}^{2}) A_{c, i}

- \frac{{Γ g}_{c, i}}{2 (1 + \frac{P_{i}}{P_{s}})} [(η_{s 2, sat} + η_{s 1, sat}) A_{s 1, i} A_{s 2, i} {A_{sat, i}}^{*} + η_{s 1, s 2} {A_{s 1, i}}^{2} {A_{s 2, i}}^{*}]

\frac{d A_{sat, i}}{d z} = \frac{1}{2} [\frac{Γ_{g_{sat, i}}}{1 + \frac{P_{i}}{P_{s}}} (1 - i α_{i}) - α_{l}] A_{sat, i} - \frac{{Γ g}_{sat, i}}{2 (1 + \frac{P_{i}}{P_{s}})} (η_{sat, s 1} {∣ A_{s 1, i} ∣}^{2} + η_{sat, s 2} {∣ A_{s 2, i} ∣}^{2} + η_{sat, c} {∣ A_{c, i} ∣}^{2}) A_{sat, i}

- \frac{{Γ g}_{sat, i}}{2 (1 + \frac{P_{i}}{P_{s}})} [(η_{s 2, c} + η_{s 1, c}) A_{s 1, i} A_{s 2, i} {A_{c, i}}^{*} + η_{s 2, s 1} {A_{s 2, i}}^{2} {A_{s 1, i}}^{*}]

g (v, N) = \frac{e^{2} {∣ M ∣}^{2}}{4 π^{2} ε_{0} {m_{0}}^{2} c n_{g} v} {(\frac{8 π^{2} m_{c} m_{hh}}{h^{2} (m_{c} + m_{hh})})}^{\frac{3}{2}} {(h v - E_{g})}^{\frac{1}{2}} [f_{c} (v) + f_{v} (v) - 1]

\pm \frac{d {W_{j, i}}^{\pm} (z, t)}{d z} = [Γ_{g_{j, i}} (N) - α_{l}] {W_{j, i}}^{\pm} (z, t) + Γ_{{g_{j, i}}^{'}} \frac{h c^{2}}{{λ_{j}}^{3}}

g' (v, N) = \frac{e^{2} {∣ M ∣}^{2}}{4 π^{2} ε_{0} {m_{0}}^{2} c n_{a} v} {(\frac{8 π^{2} m_{r}}{h^{2}})}^{\frac{3}{2}} {(h v - E_{g})}^{\frac{1}{2}} f_{c} (v) f_{v} (v)

\frac{d N_{i}}{d t} = \frac{I}{ewdL} - (c_{1} N_{i} + c_{2} N_{i}^{2} + c_{3} N_{i}^{3}) - \sum_{j = s_{1}, s_{2}, c, sat} g_{j, i} \frac{G_{j, i} - 1}{\ln G_{j, i}} \frac{{∣ A_{j, i} ∣}^{2} λ_{j}}{hcwd}

- \sum_{j = 1}^{m} g_{j, i} [\frac{{2_{g}}_{j, i}}{{\bar{g}}_{j, i}} (\frac{G_{j, i} - 1}{\ln G_{j, i}} - 1) + \frac{G_{j, i} - 1}{\ln G_{j, i}} \frac{Δ λ ({W_{j, i}}^{+} + {W_{j, i}}^{-}) λ_{j}}{hcwd}]

S1	S2	SUM	CARRY
0	0	0	0
0	1	1	0
1	0	1	0
1	1	0	1

Symbol	Parameter	Value
L	Length of active region	1×10^-3m
w	Width of active region	3.3×10^-6m
d	Thickness of active region	0.15×10^-6m
c₁	Nonradiative recombination coefficient	1.5×10⁸s^-1
c₂	Bimolecular recombination coefficient	2.5×10-¹⁷m³s^-1
c₃	Auger recombination coefficient	9.4×10^-41m⁶s^-1
α_l	Internal loss of SOA	4×10³m^-1
Γ	Optical confinement factor	0.3
n	refractive index	3.22
P_sat	Saturation power	1.0×10^-2W
α_CH	Linewidth enhancement factor by CH	3.6
α_SHB	Linewidth enhancement factor by SHB	0.1
ε_CH	Carrier heating parameter	4W^-1
ε_SHB	Spectral hole burning parameter	6W^-1
τ_s	Carrier lifetime	1.6×10^-10s
τ₂	Spectral hole burning time	1.0×10^-13s
τ₁	Carrier heating time	6.5×10^-13s
m_c	Effective mass of electron in the CB	4.10×10^-32Kg
m_hh	Effective mass of a heavy hole in the VB	4.19×10^-31Kg
m_lh	Effective mass of electron in the CB	5.06×10^-32Kg

S1	S2	SUM	CARRY
0	0	0	0
0	1	1	0
1	0	1	0
1	1	0	1

Symbol	Parameter	Value
L	Length of active region	1×10^-3m
w	Width of active region	3.3×10^-6m
d	Thickness of active region	0.15×10^-6m
c₁	Nonradiative recombination coefficient	1.5×10⁸s^-1
c₂	Bimolecular recombination coefficient	2.5×10-¹⁷m³s^-1
c₃	Auger recombination coefficient	9.4×10^-41m⁶s^-1
α_l	Internal loss of SOA	4×10³m^-1
Γ	Optical confinement factor	0.3
n	refractive index	3.22
P_sat	Saturation power	1.0×10^-2W
α_CH	Linewidth enhancement factor by CH	3.6
α_SHB	Linewidth enhancement factor by SHB	0.1
ε_CH	Carrier heating parameter	4W^-1
ε_SHB	Spectral hole burning parameter	6W^-1
τ_s	Carrier lifetime	1.6×10^-10s
τ₂	Spectral hole burning time	1.0×10^-13s
τ₁	Carrier heating time	6.5×10^-13s
m_c	Effective mass of electron in the CB	4.10×10^-32Kg
m_hh	Effective mass of a heavy hole in the VB	4.19×10^-31Kg
m_lh	Effective mass of electron in the CB	5.06×10^-32Kg