improved results for both 56 and 112 gb/s pam4 signals · improved results for both 56 and 112gb/s...
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![Page 1: Improved Results for both 56 and 112 Gb/s PAM4 Signals · Improved Results for both 56 and 112Gb/s PAM4 Signals Winston Way, Trevor Chan, and Alexander Lebedev NeoPhotonics, USA Marco](https://reader036.vdocuments.mx/reader036/viewer/2022062601/5be6063d09d3f28a428d274b/html5/thumbnails/1.jpg)
Improved Results for both 56 and 112Gb/s PAM4 Signals Improved Results for both
56 and 112Gb/s PAM4 Signals
Winston Way, Trevor Chan, and Alexander Lebedev
NeoPhotonics, USA
Marco Mazzini, Cisco, Itay
IEEE802.3bs, January 2015
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Brian Welch, Luxtera
David Lewis, JDSU
Sudeep Bhoja, InPhi
Vipul Bhatt, InPhi
Keith Conroy, Multiphy
Gary Nicholl, Cisco
Zengli, Huawei
Bharat Tailor, Semtech
Alan Tipper, Semtech
Jeffery Maki, Juniper
Vasu Parthasarathy, Broadcom
Will Bliss, Broadcom
Rob Stone, Broadcom
Fred Tang, Broadcom
SupportersSupporters
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GoalsGoals
• Improve the BER vs ROP performance of 112Gb/s PAM4
• Set bandwidth requirements on electrical and optical components
• Investigate penalty caused by SSPR over PRBS15
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112Gb/s PAM4
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Single-wavelength 112Gb/s PAM-4 Experiment: Pre- and Post-DSP
Single-wavelength 112Gb/s PAM-4 Experiment: Pre- and Post-DSP
1314 nm
EML
(31GHz)
PIN/TIA
Linear
Driver
(50GHz)
VOA
56GS/s
AWG (3dB BW
= 14.5GHz)
+6.5dBm
Offline
PAM4
DSP
(FFE, 19 taps)
160GSPS/ 63GHz
real-time scopeOffline
PAM4
DSP
(FFE,19 taps)
(see slide 6
for specs)
Received
Optical
Power
SNR= 22.5dB SNR= 22.0dB @ ROP= 4.5dBm
SNR= 20.2dB @ ROP=0dBm
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Overall Transmitter Bandwidth (DAC+Driver+EML)Overall Transmitter Bandwidth (DAC+Driver+EML)
31 GH
z
-3 dB
16.5 GH
z
-3 dB
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112Gb/s PAM4 Experimental Results112Gb/s PAM4 Experimental Results
(way_3bs_01_0914)
Low-end cutoff frequency <50KHz
Pre-distorted ER= 5.6dB
RX A RX B
Responsivity
(A/W)0.4 0.7
3dB BW (GHz) 40 30
Spectral noise
density
(pA/√√√√Hz)
40 35
2~3 times BER improvement can be done by further equalizing the three inner eye amplitudes
-7dBm
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Cisco Results with LiNb03 modulator PAM 4 TX
BER floor < 1E-5, one decade better than
previous results, as forecasted by Alan (see
tipper_01_3bs_1114), in line with Winston’s
results.
-6dBm OMA (ER=6dB) at 1E-4 BER.
No penalty observed between BTB and fiber
propagation (≈ 1dB penalty at 50ps/nm
dispersion was measured)
Overload effect due to
PIN-TIA fixed gain RX.
Previous set-up, see
mazzini_01a_0814_smf.pdfOptical Eye
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DAC 3dB BW=14.5GHz, 2nd order Bessel for
DAC
TX linear AMP BW=30GHz/50GHz
EML BW=32GHz
SNR before E/O =22.5dB, ER=6dB
WL=1310nm
RIN=-145dB/Hz
RX input noise density=35/40 pa/Hz^(1/2)
PD+TIA BW=30/50GHz, PD Respons.=0.8A/W
5th-order Bessel approximation of Tx amp,
E/O, PD+TIA
5 bits A/D ENOB, 5th order Bessel A/D, 23GHz
BW A/D
19 taps pre-correction T-spaced, 21-taps FFE
Rx T/2-spaced
Simulation Match With Experimental Results
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99
Baud rate = 56Gbaud or 51.5625Gbaud
DAC 3dB BW=16.5GHz, 2nd order Bessel for
DAC
TX linear AMP BW=30GHz
EML BW=32GHz
SNR before E/O =22.5dB, ER=6dB
RIN=-145dB/Hz
RX input noise density=30pA/Hz^(1/2)
PD+TIA BW=32GHz, PD responsivity=0.75,
400Ohm transimpedance
5th-order Bessel approximation of Tx amp,
E/O, PD+TIA
5 bits A/D ENOB, 5th order Bessel A/D, 20GHz
BW A/D
19 taps pre-correction T-spaced, 21-taps FFE
Rx T/2-spaced
56 ���� 51.5625Gbaud: Receiver Sensitivity Improvement56 ���� 51.5625Gbaud: Receiver Sensitivity Improvement
Receiver sensitivity improved by 1.2dB @ BER=2.1e-4 when the baud rate is lowered from 56 to 51.5625Gbaud
1.2dB
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DAC and Linear Amplifier Bandwidth Tradeoff (Simulation)
DAC 3dB BW is varied, 2nd order Bessel
for DAC
TX linear AMP BW=30GHz/50GHz
EML BW=32GHz
SNR before E/O =22.5dB, ER=6dB
WL=1310nm
RIN=-145dB/Hz
RX input noise density=40 pa/Hz^(1/2)
PD+TIA BW=50GHz, PD Respons.=0.8A/W
5th-order Bessel approximation of Tx
amp, E/O, PD+TIA
5 bits A/D ENOB, 5th order Bessel A/D,
23GHz BW A/D
19 taps pre-correction T-spaced, 21-taps
FFE Rx T/2-spaced
With pre-equalization, 16.5GHz DAC + 30GHz LA can achieve the same BER performance as in the experiment
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Measured 112Gb/s PAM4 BER vs ADC bandwidth (brick-wall)Measured 112Gb/s PAM4 BER vs ADC bandwidth (brick-wall)
Pre-compensated SSPR
Real-time scope frequency cutoff
ROP= 0dBm
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DAC 3dB BW=16.5GHz, 2nd order Bessel
for DAC
TX linear AMP BW=30GHz
EML BW=32GHz
SNR before E/O =22.5dB, ER=6dB
WL=1310nm
RIN=-145dB/Hz
RX input noise density=40 pa/Hz^(1/2)
PD+TIA BW=50GHz, PD Respons.=0.8A/W
5th-order Bessel approximation of Tx
amp, E/O, PD+TIA
5 bits A/D ENOB, 5th order Bessel A/D, A/D
BW is varied
19 taps pre-correction T-spaced, 21-taps
FFE Rx T/2-spaced
112Gb/s PAM4 BER vs ADC bandwidth
(Bessel 5th-order, Simulation)
Unlike brick-wall shaped, 5th-order Bessel-shaped ADC with a bandwidth >18GHz is sufficient
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56Gb/s PAM4
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Experimental SetupExperimental Setup
1295 nm
EML
(21GHz)Linear
PIN/TIA
Linear
Driver
(31GHz)
VOA
56GS/s
AWG (3dB BW
= 14.5GHz)
+5.6 dBm
Offline
PAM4
DSP
160GSPS/ 63GHz
real-time scopeOffline
PAM4
DSP
(21 taps FFE)Received
Optical
Power
22GHz/ 17pA/rt(Hz)
0.45A/W responsivity
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56Gb/s PAM4 BER vs ROP56Gb/s PAM4 BER vs ROP
TX
Extinction Ratio = 6.5 dB
RX
Low-end cutoff< 50KHz
Responsivity=0.31 A/W
<1dB penalty
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• 112Gb/s PAM4
– Using practical electrical and optical components, an error floor < 1e-5 and a receiver
sensitivity of -7dBm (average power @ BER=2.1e-4) can be achieved by using pre- and
post-FFE equalizations
– Pre-equalized TX bandwidth is ~30GHz, and receiver bandwidth is ~30GHz
– DAC bandwidth >16.5GHz, ADC bandwidth >18GHz
– No BER penalty is observed for SSPR over PRBS15 using components with < 100KHz
cutoff frequencies
• 56Gb/s PAM4
- < 1dB ROP penalty is observed at a BER of 2.1e-4 comparing SSPR with PRBS15 for
components with <100KHz low-end cutoff frequencies
SummarySummary
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