Thread Links Date Links
Thread Prev Thread Next Thread Index Date Prev Date Next Date Index

Re: [802.3_B10K] Dispersion Penalty Presentations



John,

Typically SiP transmitters would be pretty close to zero chirp. There may be some tuning you can do to create +/- chirp, however I’m not sure as to how far you could go. Setting aside a (potentially) high positive chirp requirement the rest of the 400G-FR8 transmitter specs could be met with an SiP transmitter if one so desired.

 

Any idea how high the chirp would need to be?

 

Thanks,

Brian

 

From: John Johnson <000007ff7d378f43-dmarc-request@xxxxxxxx>
Sent: Thursday, September 12, 2019 1:02 PM
To: STDS-802-3-B10K@xxxxxxxxxxxxxxxxx
Subject: Re: [802.3_B10K] Dispersion Penalty Presentations

 

Hi Chris,

 

Outside of the larger debate, I have one nit to pick.  You stated:

 

"The only presented measurements have been favorable ones using EML TX with negative chirp, which compensates for SMF dispersion at short wavelengths."

 

Actually the opposite is true:  you need positive chirp to counteract the effects of negative dispersion.  In EA modulators, strong positive chirp is easier to achieve than negative chirp, which entails more negative bias, higher modulator insertion loss and possibly decreased linearity.  Positive chirp is the “natural” operating mode of an EA modulator, and is easy to achieve with low insertion loss and good linearity. This is the reason that the CD penalty is slightly negative over a wide range of negative dispersion in the presentation by Ooe and Jackson cited below. It’s also the reason that multiple EML suppliers have presented low 10km CD penalties at 1270nm at 100Gbps (but higher CD penalty at 1330nm where negative chirp is needed). Since the 400GBASE-ER8 grid ends at ~1310nm, there is no need for negative chirped modulators for 400GBASE-ER8 At least in this regard, the 25GBd LWDM EML solution is relatively more robust than for 50GBd CWDM.

 

I can't comment on the capability of SiP transmitters for 400GBASE-ER8.  Perhaps Brian can.

 

Regards,

John

 

On Thu, Sep 12, 2019 at 2:08 AM Chris Cole <chris.cole@xxxxxxxxxxx> wrote:

Dear Colleagues,

 

The issue being raised with the 400GBASE-ER8 proposed specification is not narrowly whether there have been any dispersion measurements, but rather that the specification has not received the kind of scrutiny that is typical of 802.3 standards.

 

An example of appropriate level of scrutiny is what happened this year in 802.3cu, with the 400GBASE-LR4 proposal on CWDM4 grid supporting 10km reach. This proposal was vigorously challenged, which led to multiple iterations of measurements, broad analysis of those measurement by many individuals, and a review of the underlying assumptions behind the reach objective so that the specification actually met the Broad Market Potential criteria. This was in the best tradition of 802.3, and resulted in a revised adopted specification with 6km reach objective. Most importantly, it addressed real End User requirements, which are first and foremost low cost, which in turn will lead to a highly successful PMD.

 

This is in contrast to what has happened in 802.3cn with respect to 400GBASE-ER8 proposal on LWDM grid supporting 40km reach. In below emails, favorable measurements are listed which show that the 40km reach can just be met, just as there are favorable measurements in 802.3cu showing that 10km reach can just be met. What is missing is a range of measurements, including using different technologies.  Just as LR4 on CWDM4 grid for 10km is a stretch, so ER8 on LWDM for 40km is a stretch. Which misses the whole point of creating an IMDD spec. for >10km. There is a solution for reaches beyond IMDD capability, and that is Coherent. At some reach, in order for IMDD to be viable, it has to be substantially lower cost than Coherent, otherwise there is no motivation for End Users to proliferate optics types. They have no choice but to use Coherent. They have a choice whether to use ER8.

 

The 400GBASE-ER8 proposed specification is not low cost because there is little manufacturing margin. The only presented measurements have been favorable ones using EML TX with negative chirp, which compensates for SMF dispersion at short wavelengths. This means that other technologies, in particular MZ TX may not work. To deliberately exclude Silicon Photonics from an IEEE specification is bizarre to say the least, given the huge industry investment in Silicon Photonics technology. This investment likely exceeds investment in any other technology. 802.3 specs are not written to favor just one technology, because it is recognized that picking technology winners should not be part of the standards process.

 

The End Users have been very clear. Meeting arbitrary past reach numbers which made technical sense at lower data rates is much less important than lowest possible cost for the rate of interest. At 400G, 40km ER makes no more sense than 10km LR.

 

http://www.ieee802.org/3/cu/public/Sept19/cole_3cu_01b_0919.pdf#page=3

 

A low cost ER8 spec. needs to be targeted at a lower reach, for example 25km, so that there is ample manufacturing margin for TX power and penalty specs. and multiple technologies can be used to implement the TX. The low cost required of an IMDD optic to be competitive with a Coherent solution will not be achieved if there is little manufacturing margin.

 

The right next step is to go back and subject the current specification to vigorous review, and to obtain accurate End User feedback on what’s more important to them in a >10km IMDD PMD, 40km or low cost. Otherwise the ER8 40km spec. will not only not meet the Broad Market Potential Objective, but will quickly have no market at all as it’s supplanted by Coherent. This guidance maybe have to be provided to 802.3cn TF by the 802.3 Working Group.

 

Thank you

 

Chris

 

From: Hideki Ooe <ooe-hideki@xxxxxxxxx>
Sent: Wednesday, September 11, 2019 7:52 AM
To: STDS-802-3-B10K@xxxxxxxxxxxxxxxxx
Subject: [EXTERNAL]: Re: [802.3_B10K] Dispersion Penalty Presentations

 

Dear John,

 

Below presentation addresses TDECQ down to -200 ps/nm dispersion (with T-spaced 5-tap FFE), shown in page 5. As usual to EML, it shows negative CD penalty down to -150 ps/nm.

http://www.ieee802.org/3/B10K/public/18_09/jackson_b10k_01_0918.pdf

 

Regards,

-------------------------------------------------

Hideki Ooe <ooe-hideki@xxxxxxxxx>

Transmission Devices Laboratories

Sumitomo Electric Industries

 

 

From: Brian Welch (bpwelch) <00000e3f3facf699-dmarc-request@xxxxxxxx>
Sent: Wednesday, September 11, 2019 9:42 PM
To: STDS-802-3-B10K@xxxxxxxxxxxxxxxxx
Subject: Re: [802.3_B10K] Dispersion Penalty Presentations

 

John,

Thanks for sending, I hadn’t seen these. However in looking at them I don’t see that any TDECQ measurements were taken. Sone_b10k_01a_1117 does indicate some CD penalties, but it does so using a T/2 spaced 17-tap FFE as the receiver, which is quite a bit different that the reference receiver in use in a TDECQ measurement. Do you know of any TDECQ measurements taken (with the prescribed reference equalizer)?

 

Also, given that there are negative CD penalties  down to as low as -150 ps/nm suggests that the transmitters in use have quite a bit of chirp. Do you know if measurements were performed for any un-chirped transmitters?

 

Thanks,

Brian

 

 

From: John DAmbrosia <jdambrosia@xxxxxxxxx>
Sent: Wednesday, September 11, 2019 7:57 AM
To: STDS-802-3-B10K@xxxxxxxxxxxxxxxxx
Subject: [802.3_B10K] Dispersion Penalty Presentations

 

All,

Yesterday an issue was raised regarding dispersion, and there was an inquiry regarding any presentations on the topic had been heard.  My thanks to Peter Stassar, who did the digging through the Study Group archives to find the following presentations that had explored assessing the dispersion penalty at high negative dispersion of around -200ps/nm.  As I recall now, this was a key issue for the Study Group to resolve before it finally adopted the 40km objectives and could answer the Technical Feasibility Criteria.

 

SG material.

November 2017:

http://www.ieee802.org/3/B10K/public/17_11/sone_b10k_01a_1117.pdf

 

January 2018:

http://www.ieee802.org/3/B10K/public/18_01/yamamoto_b10k_01a_0118.pdf

 

March 2018

http://www.ieee802.org/3/B10K/public/18_03/yu_b10k_01c_0318.pdf

 

Regards,

 

John D’Ambrosia

Chair, IEEE P802.3cn Task Force

 

 

 


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1


To unsubscribe from the STDS-802-3-B10K list, click the following link: https://listserv.ieee.org/cgi-bin/wa?SUBED1=STDS-802-3-B10K&A=1