Draft N Router Coverage: When the "n" in 802.11n really means "not yet"
by Gary Key on August 30, 2006 5:00 AM EST- Posted in
- Networking
It has been over two and half years since the Institute of Electrical and Electronics Engineers (IEEE) formed a task group to develop and implement a new 802.11 standard for wireless local area networks (WLAN). The proposed standard is known as 802.11n and is designed to eventually offer speeds up to 600 Mbps (burst mode, quad spatial streaming in the 5GHz band) with average data transfer rates around 200 Mbps and ranges extending up to 200 Feet indoors. The current shipping Draft N products advertise speeds up to 300 Mbps (burst mode, dual channel streaming) with data transfer rates reaching 130 Mbps and indoor distances up to 150 feet. The current 802.11g standard offers speeds up to 54 Mbps with sustained transfer rates around 24 Mbps operating at distances up to 100 feet indoors.
The proposed 802.11n amendment has had a colorful and storied history. This proposed standard does not have the publicity of the continuing HD-DVD/Blu-ray DVD drama. However, it does have similarities in the way two camps consisting of rival competitors have bickered over a next generation standard that should have been ratified by now. During the early creation phase of this project there were two camps jockeying to define 802.11n. These camps included the WWiSE (World-Wide Spectrum Efficiency) whose primary team members consisted of Airgo, Broadcom, and Texas Instruments along with TGNSync that was led by Intel, Atheros, and Marvell.
After months of bickering, these two groups along with the newly formed MITMOT (Mac and Mimo Technologies for More Throughput) team consisting of Motorola and Mitsubishi merged into a single group known as the Joint Proposal Team. This was a short lived alliance as the team fell apart with Intel, Atheros, Marvell, and Broadcom splintering off to create the Enhanced Wireless Consortium (EWC).
The EWC did what the other members and teams could not as they were able to get the IEEE 802.11n task group to approve their specification as the proposed 802.11n standard in January of 2006. In March of 2006, the IEEE committee sent the proposal known internally as 802.11n, Draft 1.0, to its first letter ballot. The Draft 1.0 proposal failed miserably as it could not even gain a simple majority vote in favor of the proposal much less the required 75 percent majority required for ratification.
Over 12,000 comments were received from various IEEE members citing standards issues, operating frequency conflicts, and an overwhelming list of deficiencies (concerns) that include everything from power saving guidelines for handheld devices to proper streaming techniques for audio and video in media servers. In May of 2006, the IEEE 802.11 committee decided not to forward the Draft 1.0 proposal for a full sponsor vote and instead sent the 802.11n task group back to the drawing board to devise a new standard that would meet the concerns of the IEEE membership.
However, the primary members of the EWC that backed the 802.11n, Draft 1.0, specification started shipping "Draft N" product into the market shortly after the proposal was sent to its first letter ballot. This is a decision that could potentially haunt manufacturers and customers alike depending upon what the next draft proposes in the way of compliance to two main issues. While the current suppliers of Draft N products would like you to think that firmware and driver updates could potentially ensure their product is compatible with the upcoming standard there is no guarantee the products will work with the new standard properly, much less each other.
Out of the 12,000 comments about half of them have been resolved at this point through editorial content changes in the initial draft with a significant amount of the remaining comments being duplicates. However, there are a couple of issues that are at the crux of the current controversy. The two main issues with the 802.11n, Draft 1.0, proposal that are being remedied at this time include proper Clear Channel Assessment (CCA) and power-save multi-polling standards for handheld devices. The most critical issue currently is how to resolve the "bad neighbor" effect of the current Draft N hardware.
In essence, only three of the eleven 20MHz channels in the current 2.4GHz band where 802.11b, 802.11g, and proposed 802.11n standards operate do not overlap in most instances. These channels are currently 1, 6, and 11. The 802.11n Draft 1.0 proposal currently stipulates these 20MHz channels in the same frequency band while allowing for the optional 40MHz channel in the same band. This 40MHz channel capability is due to 802.11n defaulting to the use of two 20MHz channels of bandwidth via a throughput enhancing design known as channel bonding that appeared in the original MIMO (Multiple In, Multiple Out) products. The 40MHz signal can potentially overlap all of the 20MHz channels in the 2.4GHz band which allows for the disruption of any devices operating on the 20MHz channels. This creates the "bad neighbor" effect as you have the Draft N devices stepping on the legacy product signals, and this has been one of the major issues with the current release of products.
In order to solve this issue, the current recommendation is to still permit the use of the 40MHz channels but to "ensure" a method of detecting legacy networks operating on the same channel and then having the 802.11n device fall back, even temporarily, to a single or different 20MHz channel in order to avoid a collision. Current Draft N products do this to a certain degree; ensuring this rule occurs is the preferred solution but it will render most of the current Draft N devices useless with the new standard. This change will require additional hardware capability or a silicon change to properly monitor and then switch channels on the fly to guarantee proper CCA is being performed. Also, 40MHz operation will have to be optional as this channel is not available for use in Japan and sections of Europe at this time.
We currently expect the differences to be resolved in time for a second draft to be completed this November with a letter ballot going out in January of 2007. If this is approved we can expect final ratification in late 2007 or early 2008 although we very well could see a Draft 3.0 in the spring if real progress is not made this winter. However, the products released that meet an approved Draft 2.0/3.0 specification are almost certain to be fully compliant with the final 802.11n amendment. Let's see how our first batch of Draft N products performs at this time.
The proposed 802.11n amendment has had a colorful and storied history. This proposed standard does not have the publicity of the continuing HD-DVD/Blu-ray DVD drama. However, it does have similarities in the way two camps consisting of rival competitors have bickered over a next generation standard that should have been ratified by now. During the early creation phase of this project there were two camps jockeying to define 802.11n. These camps included the WWiSE (World-Wide Spectrum Efficiency) whose primary team members consisted of Airgo, Broadcom, and Texas Instruments along with TGNSync that was led by Intel, Atheros, and Marvell.
After months of bickering, these two groups along with the newly formed MITMOT (Mac and Mimo Technologies for More Throughput) team consisting of Motorola and Mitsubishi merged into a single group known as the Joint Proposal Team. This was a short lived alliance as the team fell apart with Intel, Atheros, Marvell, and Broadcom splintering off to create the Enhanced Wireless Consortium (EWC).
The EWC did what the other members and teams could not as they were able to get the IEEE 802.11n task group to approve their specification as the proposed 802.11n standard in January of 2006. In March of 2006, the IEEE committee sent the proposal known internally as 802.11n, Draft 1.0, to its first letter ballot. The Draft 1.0 proposal failed miserably as it could not even gain a simple majority vote in favor of the proposal much less the required 75 percent majority required for ratification.
Over 12,000 comments were received from various IEEE members citing standards issues, operating frequency conflicts, and an overwhelming list of deficiencies (concerns) that include everything from power saving guidelines for handheld devices to proper streaming techniques for audio and video in media servers. In May of 2006, the IEEE 802.11 committee decided not to forward the Draft 1.0 proposal for a full sponsor vote and instead sent the 802.11n task group back to the drawing board to devise a new standard that would meet the concerns of the IEEE membership.
However, the primary members of the EWC that backed the 802.11n, Draft 1.0, specification started shipping "Draft N" product into the market shortly after the proposal was sent to its first letter ballot. This is a decision that could potentially haunt manufacturers and customers alike depending upon what the next draft proposes in the way of compliance to two main issues. While the current suppliers of Draft N products would like you to think that firmware and driver updates could potentially ensure their product is compatible with the upcoming standard there is no guarantee the products will work with the new standard properly, much less each other.
Out of the 12,000 comments about half of them have been resolved at this point through editorial content changes in the initial draft with a significant amount of the remaining comments being duplicates. However, there are a couple of issues that are at the crux of the current controversy. The two main issues with the 802.11n, Draft 1.0, proposal that are being remedied at this time include proper Clear Channel Assessment (CCA) and power-save multi-polling standards for handheld devices. The most critical issue currently is how to resolve the "bad neighbor" effect of the current Draft N hardware.
In essence, only three of the eleven 20MHz channels in the current 2.4GHz band where 802.11b, 802.11g, and proposed 802.11n standards operate do not overlap in most instances. These channels are currently 1, 6, and 11. The 802.11n Draft 1.0 proposal currently stipulates these 20MHz channels in the same frequency band while allowing for the optional 40MHz channel in the same band. This 40MHz channel capability is due to 802.11n defaulting to the use of two 20MHz channels of bandwidth via a throughput enhancing design known as channel bonding that appeared in the original MIMO (Multiple In, Multiple Out) products. The 40MHz signal can potentially overlap all of the 20MHz channels in the 2.4GHz band which allows for the disruption of any devices operating on the 20MHz channels. This creates the "bad neighbor" effect as you have the Draft N devices stepping on the legacy product signals, and this has been one of the major issues with the current release of products.
In order to solve this issue, the current recommendation is to still permit the use of the 40MHz channels but to "ensure" a method of detecting legacy networks operating on the same channel and then having the 802.11n device fall back, even temporarily, to a single or different 20MHz channel in order to avoid a collision. Current Draft N products do this to a certain degree; ensuring this rule occurs is the preferred solution but it will render most of the current Draft N devices useless with the new standard. This change will require additional hardware capability or a silicon change to properly monitor and then switch channels on the fly to guarantee proper CCA is being performed. Also, 40MHz operation will have to be optional as this channel is not available for use in Japan and sections of Europe at this time.
We currently expect the differences to be resolved in time for a second draft to be completed this November with a letter ballot going out in January of 2007. If this is approved we can expect final ratification in late 2007 or early 2008 although we very well could see a Draft 3.0 in the spring if real progress is not made this winter. However, the products released that meet an approved Draft 2.0/3.0 specification are almost certain to be fully compliant with the final 802.11n amendment. Let's see how our first batch of Draft N products performs at this time.
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nullpointerus - Wednesday, August 30, 2006 - link
It really depends on your specific situation, but personally I would not advise using WiFi for streaming media servers. Even with a Linksys WRX card in the client, we would still get occasional hiccups and be forced to pause the movie while the client's buffer refilled. And of course, I would often have to grab a USB keyboard to restart the client PC when it failed to deal with the periodic connection loss.Given the time I wasted troubleshooting that, wiring ethernet into the living room was a breeze. I simply unhooked the living room cable, taped the CAT-5e cable onto it, and used the slack to pull the CAT-5 cable down into the living room. Presto! Cable TV and CAT-5 on the same jack, and _no interference_. If you can do it, wiring for ethernet is a much better proposition than spending money on expensive MIMO wireless equipment.
LoneWolf15 - Thursday, August 31, 2006 - link
Currently, I completely agree with you. My DVR is wired in through CAT5. (Note: Have used the Linksys SRX stuff and find it has its occasional quirks as well).I think that at the point high-bandwidth Wifi becomes more prevalent though, this may be less of an issue. I also think that they'll implement some sort of memory buffer as part of the networking hardware to get around your hiccup issue. It just isn't there yet. And as long as 11.n isn't fully ratified, I don't think it will be either. That's why I'd like to see the IEEE get off their rears and get this taken care of.