Re: [802.3_10SPE] Fast Link Recovery

[George Zimmerman <george@xxxxxxxxxxxxxxxxxxxx>]

As Chair, I’ll give a quick answer –

The project is still in a study group phase.  Our job is to develop the project documentation, including the “Criteria for Standards Development” (technical feasibility, broad market potential, etc.) and project objectives. We are not yet considering PHY proposals, and won’t until we have gotten an approved IEEE standards project, and are in the “task force” phase.  I too have significant background with DSL technologies, and would welcome someone from a process control background providing information on use of VDSL2 in the process control environment. At this point it would be useful as a technical feasibility touchpoint, in the future, it might be evolved into a PHY proposal.

 

I hope this helps.

 

-george

 

George Zimmerman, Ph.D.

10 Mb/s Single Twisted Pair Ethernet Study Group

President & Principal

CME Consulting, Inc.

Experts in Advanced PHYsical Communications

george@xxxxxxxxxxxxxxxxxxxx

310-920-3860

 

 

 

 

From: Dick Caro [mailto:dickcaro@xxxxxxxxx] On Behalf Of Dick Caro
Sent: Thursday, October 13, 2016 10:56 AM
To: George Zimmerman <george@xxxxxxxxxxxxxxxxxxxx>; STDS-802-3-10SPE@xxxxxxxxxxxxxxxxx
Subject: RE: [802.3_10SPE] Fast Link Recovery

 

I am new to this group, so please forgive my naiveté. My interest is mostly in the process control applications (oil, gas, petro, pulp, paper, metals, etc.) where we do need long distances – typically up to a mile, and we would prefer that inexpensive cable be used. I chaired the ANSI/ISA S50.02 standards committee in the 1990’s where we produced a standard for field instruments using a baseband trapezoidal waveform at 31.25 kbps using the technology of the late 1980’s. We had to use a two-level network to get the speeds we needed when all of the field networks were aggregated into a backbone that eventually became Foundation Fieldbus HSE based on conventional high speed Ethernet (100 Mbps). Today, we would like to do better than that and extend Ethernet all the way down to the field device so we can avoid a two-level architecture network. I had hopes for this committee’s work, but I don’t see it in your current work that seems trapped into thinking that 10 Mbps is enough.

 

There are low cost technologies that can achieve long distance and high speed over a twisted pair copper wire. However, they are not baseband technologies. The one that attracts my attention is VDSL2; ITU-T G.993.2 approved in February 2006. This is a simple carrier-based broadband technology that operates on twisted pair copper lines with a 30 MHz carrier and is capable of a symmetric data rate of 100Mbps. It was developed to deliver broadband on a basic telephone line. I wish we had this in 1990 for our Fieldbus work, but it is a commodity now. Why has this committee not considered VDSL2 for the PHY?

 

Dick Caro    See my Blog: http://dickcaro.blogspot.com/

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From: George Zimmerman [mailto:george@xxxxxxxxxxxxxxxxxxxx]
Sent: Thursday, October 13, 2016 11:38 AM
To: STDS-802-3-10SPE@xxxxxxxxxxxxxxxxx
Subject: Re: [802.3_10SPE] Fast Link Recovery

 

Oisin – thank you for raising the question.  I have understood, and perhaps been assuming, that fast link recovery was to deal with the  a drop in SNR.  In many systems, a retrain will improve the SNR.  Many systems (2.5G/5G/10GBASE-T) use a fast retrain concept to allow a more rapid startup based on the fact that echo cancellers, equalizers and timing phase may reconverge to different solutions if given the chance to retrain. I am unclear whether 40msec is feasible for a system of this baud, and whether the result has effect is dependent on how the system itself is designed.  For example, in the 2.5G/5G/10GBASE-T systems, these are all Tomlinson-harahima precoded, and the retrain allows a free re-setting of the THP coefficients – which enables quite different equalizer outputs. Other PR-related systems benefit from similar retrains, and, DFE systems do too, for example, freeing the slicer timing phase in a DFE-based system with a retrain enables convergence outside of a local minimum error state.   These types of parameters are more constrained in what they can track while the link is up than others are.

 

All of this said, a 40msec fast retrain for a PHY at only 10Mbps is pretty quick, and I’m concerned that my first reaction is that it would probably end up at a worse state than the PHY started out in by tracking the environment.  As Mehmet said on the call – it is very much tied in with the PHY design.  I am concerned that adding this as a requirement will lead us to PHY architectures and designs which are inherently less robust.

 

I agree that the best design state is that the PHY adjusts rapidly enough to account for the environment.  I don’t yet know whether this is true in the environment. 

I think this leads me to a similar point as you – the real requirement is link reliability under an environmental condition.  Some more definition or examples of the proposed environmental case might be useful.

 

-george

 

From: Cuanachain, Oisin [mailto:Oisin.Ocuanachain@xxxxxxxxxx]
Sent: Thursday, October 13, 2016 6:26 AM
To: STDS-802-3-10SPE@xxxxxxxxxxxxxxxxx
Subject: [802.3_10SPE] Fast Link Recovery

 

Hi all,

 

'Fast Link Recovery' was discussed at the ad hoc meeting but I'm not sure I understand what this proposed objective is intended to achieve ?

My own background is in PHY design (10/100/1000BaseT) but I have very little prior experience of Ethernet used in industrial environments.

There was some discussion of the objective but I am not sure I understand what is driving the proposal.

Specifically, does the proposal

(i) hope to use the 'Fast Recovery' to remedy packet reception problems (within 40ms) to prevent message loss (here I use 'message' to mean the information which, in the

    industrial protocol, is repeated multiple times in successive Ethernet packets to make the communication more robust)

Or

(ii) is it simply that industrial end-users are aware that retraining is behaviour that PHYs can exhibit when packets are being lost and the proposed

     objective hopes to ensure that should such a retrain occur it would have completed within 40ms ? (In this scenario, from the application point of

     view, the retrain manifests itself as the 'outage' depicted on slide 8 of http://www.ieee802.org/3/10SPE/public/adhoc/brandt_101016_10SPE_01a_adhoc.pdf)

 

If the intent is (i) above, then I don’t think this will achieve the desired effect. If some property of the channel changes sufficiently to cause a

drop in SNR and a retrain, then in general I expect the new link that will be established will ultimately have the same SNR as if the retrain had not

been initiated. ie. the PHY should be continuously adapting its receiver at a fast enough rate to keep up with channel variation over time. I appreciate

that this may not be the case with existing PHYs which may not have been designed with industrial environments in mind, but for a new standard they

should be in which case I would argue that the requirement to keep up with channel variations is already implicitly covered in the existing objective:

'Support 10 Mb/s operation in industrial environments'

 

If (ii) is the intent then would it not simply be better to disable retraining when using PHYs in industrial applications ? (Equivalent to setting the retrain

duration to 0ms).

 

Perhaps someone can clarify ?

 

Thanks,

 

Oisín.