Journal of Optical Communications and Networking
Vol. 9,
Issue 4,
pp. B124-B136
(2017)
•https://doi.org/10.1364/JOCN.9.00B124

Dimensioning of 112G Optical-Packet-Switching-Based Interconnects for Energy-Efficient Data Centers

Bárbara Dumas Feris, Philippe Gravey, Pascal Morel, Marie-Laure Moulinard, Michel Morvan, and Ammar Sharaiha

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Bárbara Dumas Feris, Philippe Gravey, Pascal Morel, Marie-Laure Moulinard, Michel Morvan, and Ammar Sharaiha, "Dimensioning of 112G Optical-Packet-Switching-Based Interconnects for Energy-Efficient Data Centers," J. Opt. Commun. Netw. 9, B124-B136 (2017)

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About this Article
History
- Original Manuscript: October 4, 2016
- Revised Manuscript: March 13, 2017
- Manuscript Accepted: March 14, 2017
- Published: March 31, 2017
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Journal of Optical Communications and Networking Optical Network Design and Modeling (2017)

Abstract

We present the dimensioning of an optical packet switching network for energy-efficient intra-data-center connections. Our approach relies on one or two interconnection stages derived from the time-wavelength-interleaved network concept and relying on fast wavelength-tunable lasers. We compare several options by numerical simulation to increase the bit rate of the intra-data-center links up to 112 Gbit/s. The analysis focuses on pulse-amplitude modulation (4 and 8 PAM), where a pre-distortion mechanism is introduced and three types of optical receivers are taken into account. Possible dispersion of device characteristics is taken into account. The single-stage system should enable us to connect 48 servers using 8 PAM and semiconductor-optical amplifier (SOA)-PIN in conjunction with a 62.5 GHz grid. In the two-stage configuration, this number increases up to 1488.

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Equidistant 4 PAM Levels
0.01		1/3		2/3		1
Pre-distorted 4 PAM Levels
0.01		1/3		$2 / 3 - Δ$		1
Equidistant 8 PAM Levels
0.01	1/7	2/7	3/7	4/7	5/7	6/7	1
Pre-distorted 8 PAM Levels
0.01	$1 / 7 + Δ$	$2 / 7 + Δ$	$3 / 7$	$4 / 7 - Δ$	$5 / 7 - Δ$	$6 / 7 - Δ$	1

	4 PAM	8 PAM
$B_{max}$ [GHz]	$B_{min} = 56 \cdot 2 \cdot 0.75 = 84 GHz$	$B_{min} = 37.34 \cdot 2 \cdot 0.75 = 56 GHz$
62.5	$B_{max} < B_{min}$	769 dB/nm
75	$B_{max} < B_{min}$	263 dB/nm
87.5	1429 dB/nm	159 dB/nm
100	313 dB/nm	114 dB/nm

Modulation Format	4 PAM	4 PAM	8 PAM
Receiver	APD	SOA-PIN	SOA-PIN
$P_{T x} = 15 dBm$
$P_{R x}$ [dBmm]	−16	−21.7	−13
$L_{C, \max}$ [dB]	16.7	21.6	14.1
$N_{\max, IL}$	44	142	22
N for 62.5 GHz spaced channel grid	NA	NA	22
N for 75 GHz spaced channel grid	NA	NA	22
N for 87.5 GHz spaced channel grid	NA	NA	22
N for 100 GHz spaced channel grid	29	29	22
$P_{T x} = 20 dBm$
$L_{C, \max}$ [dB]	21	25.8	18.4
$N_{\max, IL}$	123	385	67
N for 62.5 GHz spaced channel grid	NA	NA	48
N for 75 GHz spaced channel grid	NA	NA	39
N for 87.5 GHz spaced channel grid	NA	NA	33
N for 100 GHz spaced channel grid	29	29	29

Power Losses/Gain	dB
$L_{BPF}$	5
$G_{OA (booster)}$ ^a	20
$G_{OA (in-line)}$ ^b	20
$L_{f}$ ^c	0.2
$L_{connector}$	1
$L_{WSS}$	5

	Case 1^a	Case 2^b	Case 3^c	Case $3^{'}$ ^d
$N_{max}$ (servers per rack)	29	29	48	48
$L_{C} + L_{C, excess}$ [dB]	17.6	17.6	20	20
Received optical power (intra-rack interface)	−13.6	−13.6	−11.1	−6.1
$P_{in, inter-rack}$ [dBm]	1.4	1.4	3.9	8.9
$P_{R x, inter-rack}$ [dBm]	−12.8	−19.7	−5	−5
$L_{C, \max}^{'}$ [dB]	18.0	24	13.4	17.7
$N_{\max, IL}^{'}$	60	245	19	56
$N_{\max, - x - GHz}^{'}$ (racks)	29	29	19	48

	Typical	−5%(1)	−10%(1)
Case 1	$29 S \times 29 R$	$26 S \times 29 R$	$24 S \times 13 R$
Case 2	$29 S \times 29 R$	$29 S \times 29 R$	$29 S \times 29 R$
Case 3	$48 S \times 19 R$	$48 S \times 9 R$	NA
Case $3^{'}$	$48 S \times 48 R$	$48 S \times 31 R$	NA

Dimensioning of 112G Optical-Packet-Switching-Based Interconnects for Energy-Efficient Data Centers

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Journal of Optical Communications and Networking