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Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution



Jorge,

Unlike Marek, I think that this is a great discussion and very useful.

Yes, the OLT can set a rate limit on a per-LLID basis.  This is very common and available.  As far as the standards are concerned, this rate shaping happens above the MAC at the 802.1 or other switching layers.  With that said, having a rate limit on a per-LLID basis doesn't help with MMP.  If we sum up the rate limits of all of the LLIDs, it will greatly exceed the bandwidth of the coax.  It is required so there is statistical gain.  It wouldn't make sense to limit all of the LLIDs to not exceed the bandwidth of the coax.  It would be reserved fixed size pipes for every LLID and there would be no statistical gain.  Sounds like SONET.

MMP has a variable data rate for the entire downstream where the output data rate is a based on modulation order and codeword size.  The codeword size is based on the PHY deciding to shorten the codeword at the MMP boundaries.  It seems very difficult to come up with a shaping (idle insertion) for this function.  For that reason, I recommended back pressure from the PHY (also a MAC change) to get the best performance.  I think that another standard group is going in that direction as well.

Thanks,
Ed...

From: Marek Hajduczenia [mailto:marek.hajduczenia@xxxxxx]
Sent: Friday, January 11, 2013 1:10 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Jorge,

I hate to get involved in this discussion any further, but I thought the issue was not only rate limitation but also packet reordering, but perhaps it is just my imperfect reading of the thread I stopped following somewhere in the middle ...

Marek

From: Salinger, Jorge [mailto:Jorge_Salinger@xxxxxxxxxxxxxxxxx]<mailto:[mailto:Jorge_Salinger@xxxxxxxxxxxxxxxxx]>
Sent: Friday, 11 January, 2013 08:31 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Thanks Marek!

Maybe I misunderstood, but I thought that this was functionality that was already part of EPON. I guess I was mistaken? So, EPON as it stands today does not include support for different rates on different ONUs? In other words, as it stands today, do all LLIDs in all ONU need to operate at the same data rate? And to make sure I am clear, can we have some customers running at 10 Mbps, some at 100 Mbps, and some at rates in between?

Thanks!
Jorge

From: Marek Hajduczenia <marek.hajduczenia@xxxxxx<mailto:marek.hajduczenia@xxxxxx>>
Date: Friday, January 11, 2013 2:58 PM
To: "Salinger, Jorge" <Jorge_Salinger@xxxxxxxxxxxxxxxxx<mailto:Jorge_Salinger@xxxxxxxxxxxxxxxxx>>, EPoC Task Force <STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>>
Subject: RE: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Jorge, Eugene, et al.,

I think we are going in circles with this discussion. We already had discussion on OLT doing per LLID traffic shaping and such, reaching no conclusions at the time, except for the fact that it would be hard to guarantee that existing OLTs could support such function.

That said, we have to remember that within the scope of our project we cannot really go and change the way EPON works, or change requirements for existing devices. Our PAR does not allow us to do so ... so we have to tread very carefully here. The only device we could employ to do such functions would be the FCU, and even this device has only coax side interfaces in the scope of our work ...

Marek

From: Salinger, Jorge [mailto:Jorge_Salinger@xxxxxxxxxxxxxxxxx]
Sent: Friday, 11 January, 2013 07:50 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Eugene,

I don't follow the relevance of this remark. Can you elaborate for me?

If the OLT can rate limit on a per LLID basis (which is on a ONU/CNU basis), why is this not a workable approach for MMP? In other words, if the OLT can already limit traffic to a specific rate on a per-LLID basis, which can't this be the basis for having different channel capacities per ONU/CNU? I know you reference the rata adaptation as being the barrier, but given that the OLT can already control the specific allocation of traffic per LLID why can't the FCU adjust the transmission rate and compensate with the different use of time on the wire by removing idles, or filtering unneeded packets, etc.

Thanks!
Jorge

From: <Dai>, Eugene Dai <Eugene.Dai@xxxxxxx<mailto:Eugene.Dai@xxxxxxx>>
Reply-To: Eugene Dai <Eugene.Dai@xxxxxxx<mailto:Eugene.Dai@xxxxxxx>>
Date: Friday, January 11, 2013 2:10 PM
To: EPoC Task Force <STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Duane: PCS layer does not have LLID info.

Eugene Dai PhD
Principle Transport Architect
COX Communications
Tel: 404-269-8014
From: Duane Remein [mailto:Duane.Remein@xxxxxxxxxx]
Sent: Friday, January 11, 2013 2:07 PM
To: Dai, Eugene (CCI-Atlanta); STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Cc: Duane Remein
Subject: RE: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Eugene,
I believe if you rate adapt at the LLID level then there will be no problems. The PHY then needs to set-up the 3-4 profile allocations for the symbol according to the LLID distribution in its buffer (I'm assuming any implementation must buffer data for two symbols, the one being sent and the next one to be sent). We then need a very small channel (the PHY-Link, which already exists) to communicate the boundaries between the profiles; this is only 3-4 bytes of data for each symbol.
Best Regards,
Duane

FutureWei Technologies Inc.
duane.remein@xxxxxxxxxx<mailto:duane.remein@xxxxxxxxxx>
Director, Access R&D
919 418 4741
Raleigh, NC

From: Dai, Eugene (CCI-Atlanta) [mailto:Eugene.Dai@xxxxxxx]
Sent: Friday, January 11, 2013 12:50 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

We have shown that MMP is not technically feasible for FDD case, especially when rate adaption is concerned although not limited in this. We also gave our observations that in TDD case one may put one MP per burst that may make the rate adaption problem less restrictive for TDD. However, this is just an observation; I haven't seen any contribution studying MMP with TDD yet.

Eugene

From: Marek Hajduczenia [mailto:marek.hajduczenia@xxxxxxxxx]
Sent: Friday, January 11, 2013 12:29 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Ed,

To your point - in this case, we should have SMP for FDD system and may have MMP for TDD system.

Marek

From: Ed (Edward) Boyd [mailto:ed.boyd@xxxxxxxxxxxx]
Sent: Friday, 11 January, 2013 05:24 PM
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: Re: [STDS-802-3-EPOC] MMP issues with the MAC Layer Solution

Hi Andrea,

This is where we continue to not agree.  EPoC FDD is a PHY in my mind for the existing EPON MAC that exists in OLTs.  It should not make changes above the PHY.  There was the text about compatibility with 1G and 10G EPON.  I'm saying that we can't make something compatible.  I haven't come up with a way to make it compatible and I haven't seen anything that shows that it can be compatible.

Thanks,
Ed....

From: Garavaglia, Andrea [mailto:andreag@xxxxxxxxxxxxxxxx]
Sent: Friday, January 11, 2013 5:32 AM
To: Ed (Edward) Boyd; STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: RE: MMP issues with the MAC Layer Solution

Hi Ed,
Thanks for your reply, we try to address your questions/comments directly in the slides, so it is easier to discuss them - Nicola will present today during the call, let's try to have a constructive discussion.

Please allow me a couple of comments ahead: it is not intended from me to deny issues (sorry if I gave that impression), I am trying to address them instead showing how that can be overcome - I think it would be a pity to not even try to address them and I hope experts like you also contribute to the discussion in this spirit. In this regard, I believe it is beneficial to stick on the scope of the ad-hoc, which is about MMP in the coax portion of the network.

So we should not talk about MMP in OLT, rather MMP in CLT. Also we should not talk about channel bonding, TDD, etc., rather about MMP only.
Also we should not exclude MPCP augmentation for CLT/CNU, we should minimize them to make the system work - CLT is not a legacy OLT.

I hope we can both (all) agree on these points to profitably continue this discussion - thanks for your help.

Thanks,
Andrea

From: Ed (Edward) Boyd [mailto:ed.boyd@xxxxxxxxxxxx]<mailto:[mailto:ed.boyd@xxxxxxxxxxxx]>
Sent: Tuesday, January 08, 2013 19:27
To: Garavaglia, Andrea; STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: RE: MMP issues with the MAC Layer Solution

Andrea,

Thanks for the reply.  We keep going back to the same issue and you continue to deny that they exist.  The OLT needs new functionality defined for rate shaping and packet shuffling to use MMP.  This functionality is not defined in the current devices and needs to be above the PHY.  I don't see how you can argue against this point.  It is a new EPON for EPoC.  It is not just a PHY as promised.  TDD, MMP, and packet bonding are not compatible with the current EPON above the XGMII.

The delay and jitter performance of the downstream is poor by adding the MMP and extremely poor if you add in the channel bonding that you propose.   It requires two layers of buffering and packet sorting.  I'm not sure how you meet the 3ms RTT jitter specification.  Please show your proposed solution with the channel bonding so I can make sure that I understand it for the delay analysis.

EPON is a single copy broadcast downstream.  It is simple/fast and EPoC should be a coax PHY only below it. If an operator wants to get the last drop of efficiency on bad networks and they are willing to add complexity and delay for it, the DOCSIS 3.0/3.1 solution is a better fit.

Please see in-line below. Thanks.

Ed...

From: Garavaglia, Andrea [mailto:andreag@xxxxxxxxxxxxxxxx]<mailto:[mailto:andreag@xxxxxxxxxxxxxxxx]>
Sent: Tuesday, January 08, 2013 5:41 AM
To: Ed (Edward) Boyd; STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: RE: MMP issues with the MAC Layer Solution

Hi Ed,
Thanks for the summary.

Let's see if we can make a step forward in understanding better the concerns and how can they be addressed.
I inserted my feedback below, for further discussion.

Thanks,
Andrea

From: Ed (Edward) Boyd [mailto:ed.boyd@xxxxxxxxxxxx]
Sent: Tuesday, January 08, 2013 02:09
To: STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx<mailto:STDS-802-3-EPOC@xxxxxxxxxxxxxxxxx>
Subject: [802.3_EPOC] MMP issues with the MAC Layer Solution

Jorge, Duane, and All,

I have some concerns about reshuffling the packets in the MAC based on destination.  Here are a few of the issues that I brought up at the last meeting.


1)      Not a PHY layer solution.

a.       It won't work with existing standard compliant EPON OLT MACs. I believe that this is out of scope for our project and it severely impacts the economic feasibility for EPoC.
[AG] I tend to agree that OLT is out of scope of this project; in fact we have CLT and CNU, and we cannot assume the CLT is an OLT.
That said, I fail to see why it should not work - in the example we have shown there is no change to 802.3 MAC and I cannot see any particular change in the MPCP parts either: simply the rate adaptation (which will be needed for coax and still have to be defined in details) will use different computation parameter based on the active profile(s). The function will be the same and will need to be parameterized anyway as the coax rate can be quite variable from case to case even with single profile.

[Ed] I don't understand your response.  The solution proposed requires new OLT functionality and it is not compatible with existing OLTs.  It doesn't matter where you define it outside of the PHY.  It doesn't exist so it is not compatible and it requires additional define outside the scope of the project.  EPON over Coax should leave EPON alone.


b.      Higher layer solutions today assume point-to-point Ethernet with packet ordering happening at the bridging or routing layers.  Having a packet reordering based on the destination of packets below the MAC with a variable delay goes against this direction.
[AG] In the solution we presented there is no reordering of packets, neither above nor below MAC. Simply the Multi-Point Transmission Controller apply a different algorithm (which I like to remind is as per today already proprietary and implementation dependent) when selecting which client to serve. This can be done by proper design of the scheduler which is listed in clause 77.2.1 ("The scheduling algorithm is implementation dependent, and is not specified for the case where multiple transmit requests happen at the same time."), and does not preclude any option and certainly allow an implementation to offer only single profile as well.

[Ed] In the current solution, the downstream MAC/PHY is a pass through device. There isn't shuffling of packets to group them.  The shuffling is not reversed on the output so a packet is jitter.  The scheduler has no definition and in fact, it does nothing.  The proposed solution requires adding scheduler functionality that doesn't exist. It is not compatible for that reason.

The downstream right now looks exactly like point to point Ethernet.  We shouldn't decrease the performance and break this model.  It isn't perform like EPON or Ethernet.  This is not fiber performance.
[AG] In term of throughput, I would see MMP closer to fiber performance than SMP, as in average a larger data rate will be available on the coax since there is no need to run at the speed of the slowest user. In term of latency/jitter there may be some small increase at application level based on the particular implementation of the algorithm and of the system parameters, but this is well below the target of the current PHY layer assumptions.

[Ed] The fiber has a fixed delay and data rate.  This solution is not like Ethernet or EPON with QoS/packet ordering is handled at the higher layer.  Shuffling and jittering packets in the MAC layer is a mess.  The data rate is based on the amount of spectrum available and not the position of the modem in the network.


2)      Jitters the downstream packets

a.       For the MMP, I proposed a PHY layer solution with packet time stamping.  I had the packet time stamping so packets would be in the same order at the CNU with a fixed delay.

b.      The MAC layer solution doesn't provide this function so there are a few issues.
[AG] In the MAC solution the order of packet is not changed: at each CNU the same order will be received as transmitted. Also there is no jitter as all operations of selection of the MAC Client for transmission are made before MAC, in the Multi-Point Transmit controller - when a client is selected, its transmission will be enabled as today and no jitter is introduced - when the packet leaves the MAC, it reached the CNU counterpart after a fixed delay. Therefore there is no need to timestamp to support MMP in this solution.

[Ed] When you shuffle packets, the packets are jittered on the downstream.  They do not enter and exit with the same delay.  If you timestamp the packets and add a play out buffer at the output, you can remove the jitter.  This adds delay but doesn't add the jitter.

Right now, the assumption is that there is almost 0 jitter in the downstream for the MEF 23H jitter specification (3ms RTT).  I used the entire 3ms in my analysis for the upstream polling jitter and discovery windows.  Any jitter in the downstream will require a higher upstream polling rate or violate the specification.

c.       My analysis showed that a small pipe of 24MHz will have multiple milliseconds of delay and in the MAC solution, it is jitter.  It is impossible to meet MEF23H for small pipes and the larger pipes will require higher upstream polling to make up for it.
[AG] As commented last meeting, if the pipe is very small, a single profile can be configured and used (in addition the parameters of the MMP implementation can also be tuned) - I believe 24 MHz is rather the exception than then rule for a system which is supposed to be running at speeds of 1 Gb/s and above. Question for MSO: are we expecting a lot of deployments using only such a small bandwidth or are these corner cases? Appropriate configuration applies in any case, so I cannot see this to be a real issue.

[Ed] As the pipe cuts in half, the efficiency is half or the delay is double.  24MHz is the smallest channel that we support and it shows that the solution isn't usable but it is going down on the way.  Based on your channel bonding proposal, each of these channels would face this delay with its own shuffling logic so it is very messy.


d.      Obviously performance monitoring protocols that work above the MAC will not work.
[AG] Could you explain why not? I expect a performance monitoring tool shall not assume how the system is implemented in the lower layers and shall actually work for various configurations and implementations.
[Ed] It is expected that the MAC/PHY has a fixed delay and performance.  This solution varies the delay (by shuffling packets between stations) and data rate based on the other traffic.  The priority of my traffic is not used to determine the order to the output.


3)      GATE frame will break up the shuffled blocks of packets.

a.       The scheduler in the OLT will send the GATE at the exact time that it should go out to decrease the RTT time to get the REPORT.

b.      The scheduler is not aligned with the blocks of blocks out from the MAC so GATE frames will come out when another MMP block of packets is present.
[AG] According to the specification (see figure 77-4), the selection between GATE messages and data packets happens at the Control Multiplexer, which is in charge of prioritizing control frames (e.g. GATE) over data frames. In my understanding there is one instance of such control multiplexer for each MAC Client and whether a GATE or another frame is selected in there has nothing to do with the selection of the transmitting MAC Client itself by the multi-point transmit controller. Also the timing for the GATE messages is determined by the DBA agent, which is also proprietary and implementation dependent, I cannot see any issue in generating GATEs when they are needed, at most is a matter of optimizing proprietary algorithms to achieve better performance, something that should be done anyway.


c.       Another short FEC termination will be needed for the GATE so the GATE frame can go out immediately.  This will result in a lower efficiency based on the RATE of the upstream bursts.  Based on the numbers in my presentation, it will significantly increase the data rate for GATE frames.  Small bursts in the upstream are common with high data rate polling.
[AG] See above - all this is not needed, the control multiplexer still prioritize GATE messages over data and those are treated as any other frame of that profile.


d.      If the GATE waits for its MMP block to come up, it will increase the RTT time for REPORT to GATE.
[AG] Maybe I am missing something here, but I do not see how this can be the case: to be able to send a REPORT, a GATE should first provide the CNU with corresponding grant - so the REPORT will be sent after getting the GATE and apart a possible delay of the very first message exchange when the CNU starts up, the RTT for REPORT to GATE (from XGMII at TX to XGMII at RX) remains the same and it is determined by the PHY processing and propagation time.

[Ed] I don't know how to explain this.  The GATE frame comes out based on the scheduler.  If it is not going in the MMP block that is currently going out, the MMP block needs to break up the FEC block or delay the GATE until the proper FEC block comes around.  It is either very inefficient or it adds a millisecond or more to the schedulers delay to generate a GATE.  This goes into the REPORT/GATE loop.


4)      Small Pipes have long delays or poor efficiency.

a.       As mentioned in my PHY solution, small pipes are inefficient or have long delays to support packet re-ordering.

b.      If the pipe is 50% of the BW and the efficient is the same as a 1Gbps pipe, the delay for a block of packets would be doubled.

c.       If the pipe is 50% of the BW and delay is constant, the overhead for the FEC would be doubled.
[AG] Again, the number of profiles and the choice to use one or more can be tuned accordingly, as well as the parameters of the MMP implementation can be properly selected. In our presentation we have shown examples of possible tuning and shown that the possible additional delay can be controlled.
[Ed] In short, we can't support MMP on smaller pipes.


Hope that helps as a starting point.  I will try to be on the call at 6am.  I can't imagine mixing this with the channel bonding proposal.  The delay and jitter would be crazy and it would be very complex to implement.  I think that the performance in the downstream shouldn't be compromised.  Simple, cheap, fast, wide pipe is Ethernet.

Thanks,
Ed...


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Edward Boyd | Sr Technical Director
Broadcom Corporation | (O) 707-792-9008 | (M) 707-478-1146

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