Fat channel intolerant что это

Fat channel intolerant что это

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Настройка 802.11n на WLC — Часть 5

Если сеть не состоится только 802.11n клиенты, используйте Смешанную защиту режима так 802.11n, клиенты сосуществуют с существующим 802.11a или 802.11 b/g клиента. Если в ближайшее время вы планируете провести модернизацию компьютерного парка, то качественный ИТ-аудит вам поможет.

Установите Ширину канала или в Автоматическом режиме, таким образом, клиент выполняет согласование о ширине канала с WLC, или в 20 МГц, если это — 2.4 полосы Частоты ГГц. Если обслуживание компьютеров выполняет квалифицированными инженерами, то они легко справятся с этими задачами.

Примечание. Cisco поддерживает 40 МГц только в полосе на 5 ГГц. Заставьте опцию ширины канала в Автоматический использовать ширину канала на 40 МГц. Однако удостоверьтесь, что ширина канала на 40 МГц включена на WLC.

Отключите свойство Fat Channel Intolerant для разрешения Связывания Канала на 40 МГц.

Forum

Does anyone know the technical details behind Intel’s 5100 AGN client device setting called «Fat Channel Intolerant» ?

Their website is poor on technical details. In brief, it says «it communicates to surrounding networks that the Wi-Fi adapter is not tolerant of 40 Mhz channels in the 2.4 GHz band». Elsewhere it mentions being incompatible with 802.11n — duh.

Is this merely the way of telling the adapter to only make 20 MHz connections, or is it some broadcast that tells nearby neighbors not to use it also ?

My guess is the former — but the opposite would be good to know about.

My understanding is setting that flag does both — tells the card not to use 40 MHz channels and also begs the neighbours not to use 40 MHz channels as well.

I say beg because I did some poking around on some Aruba gear at my place and it looks like ArubaOS is set to ‘Honor 40 MHz Intolerance’ by default but it is just a check box [url=http://www.flickr.com/photos/simplywifi/5798295274](see screenshot here)[/url] so anyone could simply decide not to honor that setting at any time. I can only assume other enterprise vendors have a similar toggle. Not sure about home gear though.

Seems like a good option for 2.4 GHz in theory, but if people can just turn it off I’m wondering how effective it really is.

In case anyone is interested, here is a screenshot showing the 40 MHz intolerance bit in Wireshark — [url=http://www.flickr.com/photos/simplywifi/5797819731](Intolerance bit not set)[/url]

WLANMAN, why wouldn’t an agn card be n capable? I just did a quick search on 5100AGN . looks like an old intel card that was designed during pre-n era. is that the one you’re referring to? Looks like 5300 is the newer card, post n ratification.

I agree with you both that it does seem like a smart option, to be able to request no 40 MHZ channels for 2.4. (Of course, why not just run 5GHZ and be done with it.) But «not allowing» doubled channels on the device itself at 2.4 almost seems useless to me; who would want to do that anyhow, and is INTEL just proecting people from themselves? =) But the idea of it being able to tell neighbors seems it might be useful. of course if I were running a 40 MHZ network and some yahoo card was able to bump me down to 20 I might be irritated. I am curious about exactly how this feature works now, what it specifically does. Thanks for the screen capture btw SimplyWiFi. Interesting that the bit’s set by default. I wonder if any of the SOHO devices address this option. Something more *sigh* to research! =) Good stuff!

Here’s the intel whitepaper I saw for INTEL’s cards: http://www.intel.com/products/wireless/adapters/5000/index.htm?wapkw=(5100)

Setting the «Fat Channel Intolerant» and at the same time allowing your own device to allow 40MHZ is what would be incompatible. Which Intel seems to agree with.

It would definitely not be «playing nice» to run 40MHz yourself, and not let your neighbors to do the same.

If you are running 40 MHZ channels in a sea of 2.4 GHZ 20 MHz channels you’re definitely being a bandwidth «road hog» — that is, if you are not following the rules.

I live in an area where several people are running «pre-n» AP’s. In this case Belkin. They defineitely don’t «play nice», and stomp all over everyone elses 20MHz wide comms. They don’t seem to care what is going on around them.

What is fat channel intolerant?

Fat channel intolerant: When enabled, the client informs access points that it doesn’t support 40 MHz channel-widths in the 2.4 GHz band. 20/40 Coexistence: Enables coexistence techniques, which prevents the access point from using 40 MHz wide channels if it will interfere with any other detected networks.

How do I disable Fat channel intolerance?

In the Property: box, click 802.11n Mode and select Enabled from the drop-down menu under Value:. In the Property: box, click Fat Channel Intolerant and select Disabled from the drop-down menu under Value:. NOTE: You may need to uncheck the box next to Use default value to make any changes.

What WiFi mode is best?

If you want maximum throughput and minimal interference, channels 1, 6, and 11 are your best choices. But depending on other wireless networks in your vicinity, one of those channels might be a better option than the others.

Should I enable Xpress TM technology?

Broadcom’s Xpress Technology is one of the older performance-enhancing WiFi technologies, designed to improve wireless network efficiency and boost throughput. . It is not recommended to use Xpress in newer network environments (802.11n/ac), and with gaming, as any repackaging of data can introduce some delay.

Is Xpress technology good?

It is not only designed to improve network efficiency but also boost throughput speeds and is particularly successful in mixed environments. It is one of the early enhancement technologies designed for 802.11 but it was preceded by Intersil’s Prism Nitro and Atheros’ Super G.

How to Use the StudioLive AI Fat Channel

16 related questions found

Which wireless mode is best for gaming?

5GHz networks are more reliable than the older 2.4GHz band, but have a downside of a shorter range. Some older devices only support 2.4GHz Wi-Fi, but you can take advantage of 5GHz with newer devices, making a dual-band model vital. If you have to use Wi-Fi for gaming, use the 5GHz band if your system supports it.

Is 20MHz or 40MHz better?

A 20MHz channel width is wide enough to span one channel. . In crowded areas with a lot of frequency noise and interference, a single 20MHz channel will be more stable. 40MHz channel width allows for greater speed and faster transfer rates but it doesn’t perform as well in crowded areas.

What should my router settings be?

• 802.11 n Support. Enable: Faster speed by supporting N or later wifi tech. .
• WMM Settings. Enable: Many mobile devices like iphone and ipad need it to function. .
• 2.4 Ghz vs 5 Ghz. .
• 20 Mhz or 40 Mhz (And Best Wireless Channel) .
• AP Isolate. .
• IP Flood Detection. .
• Multicast Rate. .
• Preamble Type.

Which channel bandwidth should I use?

In most cases you should use 2.4 GHz to optimize for distance and 5 GHz to optimize for speed. However, there is a tradeoff between increased performance and range of coverage. 5 GHz is faster. 5 GHz Wi-Fi offers faster uploads and downloads than 2.4 GHz.

What wireless mode should I use for 2.4 GHz?

For the wireless mode, it is recommended to select B/G/N on the 2.4 GHz network. A/AC/N is recommended on the 5GHz network. This will allow all devices to connect to this network.

How do I change from 2.4 GHz to 5GHz?

1. Click on the WiFi icon in the bottom right corner of the task bar.
2. Then click on the network you want to use from the list of available networks.
3. Click Connect (type in the password and click Next if it’s your first time connecting to this network).

Should I disable ARP offload?

RECOMMENDATION: Keep this turned off. This offload is enables a feature where your computer responds to packets in sleep state. Unless you use that, there’s little reason to leave it on.

Should I enable 40MHz intolerant?

1 Answer. No, you shouldn’t disable that setting if any of your client devices use Bluetooth and sometimes need to use 2.4GHz Wi-Fi. What Netgear calls «20/40MHz coexistence» is probably just the required respect for the «40MHz intolerant» bit that some clients set.

How can I improve my WiFi card performance?

1. Select a Good Place for Your Router.
2. Keep Your Router Updated.
3. Get a Stronger Antenna.
4. Cut Off WiFi Leeches.
5. Buy a WiFi Repeater/ Booster/ Extender.
6. Switch to a Different WiFi Channel.
7. Control Bandwidth-Hungry Applications and Clients.
8. Use the Latest WiFi Technologies.

What is the best 802.11 mode?

In basic terms, 802.11n is faster than 802.11g, which itself is faster than the earlier 802.11b. On the company website, Apple explains that 802.11n offers «greater performance, more range, and improved reliability».

How do I make my WiFi faster?

1. Turn things off and on again. .
2. Move your router to a better location. .
3. Adjust your router’s antennas. .
4. Make sure you’re on the right frequency band. .
5. Prune unnecessary connections. .
6. Change your Wi-Fi frequency channel.

How can I make my WiFi router faster?

1. Automate a Reboot Schedule. .
2. Make Your Router Faster With a New Antenna. .
3. Disable Older Wireless Protocols. .
4. Change the Channel Width.
5. Keep Your Router Updated. .
6. Experiment With Router Location. .
7. Optimize Your Router’s Channel Settings.
8. Switch the Router to a Different Band.

What is the best channel for 2.4 Ghz?

The recommended channels to use on 2.4 Ghz are Channel 1, 6 & 11. As can be seen in the above diagram, these channels do not overlap into each other. In general 2.4 Ghz should be considered a legacy band for older devices that do not support 5 Ghz. It is often more crowded and less performant than 5 Ghz.

What is the best channel width for 2.4 GHz?

Set 2.4 GHz WiFi channel width to 20 MHz

So, if you were to choose a wider channel width that bonds multiple overlapping channels in this band, it is more likely than not that you will experience a weaker wireless performance than the expected faster speeds.

Should I enable 160 MHz router?

Best answer: To get as much speed as possible from your Wi-Fi 6 router, 160MHz is a must. For most homes, however, the speeds available at 80MHz are more than enough.

Does changing router channel increase speed?

Selecting the proper Wi-Fi channel can significantly improve your Wi-Fi coverage and performance. . Currently, many wireless routers automatically select the channel for you upon initial setup, where depending on your wireless environment, it could lead to slow Wi-Fi speeds and interference.

How do I make my WiFi faster for gaming?

1. Check Your Internet Speed and Bandwidth. .
2. Aim for Low Latency. .
3. Move Closer to Your Router. .
4. Close Any Background Websites and Programs. .
5. Connect Your Device to Your Router via an Ethernet Cable. .
6. Play on a Local Server. .
7. Restart Your Router. .
8. Replace Your Router.

What is the fastest wireless mode?

If you’re looking for faster Wi-Fi performance, you want 802.11ac — it’s that simple. In essence, 802.11ac is a supercharged version of 802.11n. 802.11ac is dozens of times faster, and delivers speeds ranging from 433 Mbps (megabits per second) up to several gigabits per second.

Network Adapter Optimization

The information in this article is intended to improve understanding of all common and advanced network adapter settings under current Windows versions. We will also offer some general suggestions on setting up your LAN for the best possible network performance. Keep in mind that many of these settings can significantly affect performance and reliability in a good or bad way. Consider testing performance using some type of network analyzer or even a simple throughput test before and after making changes. Many settings depend upon your particular network and usage.

General Recommendations

Use quality brand name network adapters — as trivial as this may sound, using a good quality Gigabit Intel/Broadcom network adapter helps improve throughput, reduces CPU utilization when under load, provides for good driver support, etc. While a basic off-brand NIC may suffice for casual use on a home computer, any tech-savvy power user, if you use P2P appliactions, media streaming, gaming, or running any type of server, you should opt for a good brand NIC for better reliability and performance under load. Good quality NICs will also have more of the advanced adapter settings listed below.

Use latest adapter drivers — Using the latest drivers from your NIC vendor can solve any issues with buggy driver support for advanced NIC functions. Also, downloading drivers from your NIC vendor rather than the Windows defaults may provide additional advanced driver settings that can be fine-tuned by the user.

Use Gigabit devices — Gigabit is very popular, especially with the ever-increasing needs to transfer huge amounts of data over the network. Streaming multimedia from NAS devices, P2P, very fast broadband connections, multiple clients using the network resources at the same time, IPTV, etc. can all strain available resources. Use Gigabit Network adapters and switches, when possible, it increases network transfer speed 10 times over 100Mbps connections.

Switches are better than hubs — Hubs broadcast packets to all ports and introduce collisions, use switches whenever possible. The difference is especially apparent in UDP-based transfers like online gaming, for example — a hub can cause 5% or more increase in the experienced packet loss (depending on the size of the hub and its current usage).

Use CAT-6 Cables — Using quality network cables can be very important, as they vary in impedance, can cause crosstalk, dropped packets, etc. Unfortunately, price of network cables does not directly correlate to price, you may have better luck buying cables from a reputable vendor that uses quality components and actually tests each assembled cable properly. Buying newer standards (i.e. CAT-6 vs. CAT-5) should be preferred, especially in Gigabit environments.

Avoid Interference — Do not coil cables, avoid running network cables near possible sources of EMI (fluorescent lights, power supplies, monitors, etc.)

Changing Network Adapter Settings

Network adapter settings can be adjusted from Control Panel -> Network and Internet -> Network and Sharing Center -> Change adapter settings -> right-click on your network adapter and choose «Properties» -> click the «Configure» button

Alternatively, right-click on the Network adapter icon in the system tray and open Network and Sharing Center -> click «Change adapter settings» in the left pane -> right-click on your network adapter and choose «Properties» -> click the «Configure» button

Network Adapter General Settings

Speed and Duplex: Just as the name suggests, this allows for selecting the desired speed and duplex of the network adapter, the default setting is usually auto negotiation. It is recommended to set the highest speed your adapter supports (Gigabit, if supported), full duplex (two-way simultaneous communication), and auto-negotiation (enabling the adapter to negotiate the highest possible reliable speed). It may sometimes be necessary/helpful to manually set the adapter speed instead of using auto-negotiation.

Gigabit Master Slave Mode: Determines whether the adapter or the link partner is designated as the master; the other end of the link would be the slave. When this is set at the default (usually «Auto Detect», or «Hardware Default»), the devices automatically negotiate this based on the IEEE 802.3ab standard: multi-port devices such as switches become the master when connected to a single port device. If both ends are multi-port devices, the one with higher seed bits becomes the master.

MAC Address / Locally Administered Address: Enables overriding the default MAC address of the adapter by the user. This is an example of how easy it is to bypass MAC address filtering techniques; do a simple packet capture to find an authorized MAC address and apply it here in the advanced settings. However, a more legitimate use of this could be changing the MAC to match the address authorized by your ISP when you’re connecting a PC directly to the modem.

Log Link State Event: This allows you to enable or disable logging of the adapter’s link state changes (such as up/down, duplex mismatch, and STP detection) in the system logs.

QoS Packet Tagging: Enables the adapter to send and receive 802.1p QoS and 802.1Q VLAN indications.

Disable unnecessary network protocols: under the Network Adapter Properties dialog, you can find a list of protocols currently in use. Each additional network client, service or protocol places additional overhead on system resources, and may introduce unnecessary network bindings and traffic. In many cases, only the following components are required for a standard TCP/IP based network:
— Client for Microsoft Networks — allows a computer to access resources on the MS network
— File and Print Sharing for Microsoft Networks — necessary to share local folders
— Internet Protocol Version 4 (TCP/IPv4) — necessary logical connection between network devices, superseded by the newer IPv6

These other services can usually be safely disabled without affecting connectivity:
— QoS Packet Scheduler — Quality of Service packet scheduler designed to control and prioritize IP traffic for various network services as a method of bandwidth management.
— Microsoft Network Adapter Multiplexor Protocol — kernel mode driver used for network card bonding.
— Microsoft LLDP Protocol Driver — Link Layer Discovery Protocol (LLDP) is a protocol for network devices to advertise their identity and neighbors, used for a network map.
— Link-Layer Topology Discovery Responder — kernel mode driver responsible for displaying the computer on a network map.
— Link-Layer Topology Discovery Mapper I/O Driver — used to discover other networked devices on a network map, and determine network bandwidth.
— Internet Protocol version 6 (TCP/IPv6) — latest revision of the Internet Protocol (IP), extending the v4 IP address limitation.

Advanced Settings

Jumbo Frames: This allows for increasing the standard 1500-byte MTU Ethernet frames to carry up to 9000 bytes of data. Using jumbo frames can help increase throughput and decrease CPU utilization on Gigabit LANs, however, the functionality and the same frame size needs to be supported by all devices on the network.

Receive Side Scaling (RSS): This enables the distribution of incoming network processing across multiple processor cores in multi-core computers, to help increase performance. It is the same setting that can be enabled/disabled at the OS level using our tweaking articles and the TCP Optimizer for newer Windows versions.

Adaptive Inter-Frame Spacing: This setting enables a time gap between packets to help compensate for excessive Ethernet packet collisions on the network.

Flow Control: Helps increase the efficiency of traffic regulation for connections that both support flow control frames. These frames are sent by an adapter when their receive queues reach a predefined limit, to signal the sending station to pause transmission so the adapter does not drop the packets. The implementation of Flow Control (Rx & Tx) in some Network Adapters is known to be buggy, likely at the driver level (Realtek Gigabit adapters confirmed). Flow control does not work well with QoS, and is generally not recommended. Disabling this feature can help reduce timeouts and improve throughput.

Interrupt Moderation Rate (coalescing): Sets the rate at which an adapter interrupts the system to handle incoming or outgoing packets. A lower rate causes the system to be more responsive to packet handling, but can decrease performance of other applications and services on the machine. A higher rate means less responsiveness of packet handling but can help increase machine performance, especially useful for when the adapter is sending and receiving larger packets. Interrupt Moderation should be disabled to get the lowest possible latency (at the expense of a bit more CPU utilization). It should be disabled for gaming, and set at a very conservative setting for pure throughput unless you are aiming for low CPU utilization at the expense of some possible delay.

Receive/Transmit Descriptors: Both settings are used to sets the number of descriptors that are allocated in the host memory for storing either received packets, or packets to be transmitted. These buffers can be increased to improve network performance if there is plenty of memory available.

Gigabit Lite: This is a legacy setting developed by Alcatel in 1998, generally supported by Realtek adapters. It allows for 500Mbps transfers over longer cable lengths, it is rarely used and should be turned off in residential settings. We recommend disabling this setting.

Offloading Settings

Note that some of the «TCP offload» settings should be applied both globally at the OS level, and in the Network adapter properties. They have to be supported by the OS and the adapter to work. Offloading works better with fast/quality network adapters, and has been plagued by buggy implementations in the past. It can help reduce CPU utilization and power consumption, and it can improve throughput in some scenarios. However, some offloads (TCP Offloads, LSO Offloads) can can also add some latency to the connection, and introduce issues. We generally recommend enabling only Checksum offloads, and disabling other types of TCP offloads, because of many buggy driver implementations causing timeouts, incomplete file transfers, known SQL server issues, etc. See our broadband tweaks articles for more information.

IPv4/TCP/UDP Checksum Offload: Enables the adapter to compute the IPv4/TCP/UDP checksum of packets instead of the OS, which reduces CPU utilization, and may theoretically increase adapter performance. This should be set to «enabled» in most common scenarios.

Offload TCP Segmentation: Allows the adapter to perform any necessary TCP segmentation of outgoing packets instead of the host OS, which can help increase transmission performance while also reducing CPU utilization. We recommend turning this off because of buggy implementations.

Large Send Offload / Large Receive Offload: This is enabled by default on many Intel/Broadcom adapters, however, there are known issues with its implementation. We recommend disabling this setting to avoid incomplete FTP file transfers and other sporadic internet issues.

Receive/Transmit Buffers: The buffer size of system memory that can be used by the adapter for received packets. This can be increased to help improve performance of network traffic, at the expense of some system memory. Intel adapter drivers usually have this setting under the network adapter properties -> Advanced -> Performance Options: «Receive Buffers» and «Transmit Buffers». Default is usually between 128 and 256 for both, it can be increased to 512, or even up to 1024 on systems with plenty of RAM to spare. This recommendation is true for both gaming/latency and pure throughput optimizations. Generally these buffers shouldn’t be set to less than 256, as they can cause dropped packets and performance degradation if exhausted. For example, with a Realtek Gigabit LAN, increasing transmit buffers from the 128 default to 256 can give up to 30% transfer speed boost to a NAS.

ARP Offload: Enables the adapter to respond to ARP requests, which prevents the computer from having to wake for them when asleep.

NS Offload: Enables the adapter to respond to Neighbor Discovery Neighbor Solicitation requests, which prevents the computer from having to wake for them when asleep.

Power Saving and Wake-On-LAN

In general, «Energy Efficient Ethernet (EEE)», «Green Ethernet» and «Power Saving Mode» settings allow for lower power consumption during periods of low network activity, with the goal to reduce power consumption by 50% or more while retaining full compatibility with existing equipment. Consumer Ethernet switches that support EEE automatically adjust their respective power-saving settings to match the adapters, but some switches are known not to perform this properly, resulting in poor throughput and increase in dropped packets. This is why we recommend turning off the EEE and Green Ethernet settings with residential setups in general to eliminate possible dropped packets, reduced throughput and occasional disconnects.

Energy Efficient Ethernet (EEE): Allows the network adapter to toggle power saving mode on or off when not in use, while still keeping the connection active. Recommended: Disabled unless laptop on battery.

Green Ethernet (Short Reach Mode): Reduces the adapter’s power consumption if the connected cable is detected under a certain length. Recommended: Disabled unless on battery.

Power Saving Mode: We recommend disabling this setting unless on battery.

Auto Disable Gigabit: When enabled, any Ethernet connections will be limited to 100Mbps, which requires less power. May be useful for laptops when using battery, to reduce power drain. We recommend disabling this to get gigabit speeds.

Wake on Magic Packet: Enables you to remotely power on the computer from sleep, hibernation, or when fully powered off by using the magic packet of the Wake-On-LAN feature.

Wake on pattern match: Enables you to remotely power on the computer from sleep, hibernation, or when fully powered off by using the pattern of the Wake-On-LAN feature.

Shutdown Wake-On-LAN: Enables Wake-On-LAN functionality if the computer is fully shutdown.

Wake-On-LAN and Shutdown Link speed: Specifies the link speed of the adapter when the computer is in sleep or hibernation.

Wireless Adapter Advanced Settings

Below is a number of additional wireless options that generally exist in some more advanced network adapter drivers (802.11ac Broadcom, Intel, ASUS, etc.).

20/40 Coexistence: When enabled, allows the 802.11n radio to drop from 40MHz mode to 20MHz mode when it detects interference. This allows it to coexist with older 802.11g radios that do not support 40MHz wide wireless channels.

40 Mhz Intolerant/Fat channel Intolerant: Setting forces the use of 20MHz channels only when enabled. Wider channels may be needed for higher throughput.

802.11n Preamble: Preamble type is an error checking function that helps with data transmission when signals are weak. Long Preamble is needed for older 802.11b/g adapters, for weaker signals (lower RSSI), while strong signals and 802.11n/ac devices generally work well with short preamble. The short preamble will yield slightly better performance if the signal is strong and there is no packet loss, however, it needs to be set the same on all devices (routers/access points/repeaters). In noisy wireless environments, for better compatibility, and in low-signal distant connections it is best to use long preamble.

Afterburner: Proprietary Broadcom throughput boosting technique used with 802.11g only, must also be supported by the access point. Only use with 802.11g adapter and compatible AP, disable otherwise.

Antenna Diversity: wireless technique that uses multiple antennas to receive or transmit signals along different propagation paths to compensate for multi-path interference. Useful, if available.

Assoc Listen Interval: A number of beacons that a «dozing» adapter is not listening for beacon frames. It is a power-saving technique where the adapter signals an interval to the access point. The access point then should not drop any queued frames until the adapter’s Listen Interval elapses. Usually defaults to 1.

Association Roam Preference: When a specific band is preferred (2.4GHz or 5GHz), and the client encounters a dual AP with the same SSID for both bands, this setting chooses which band to use. Generally 2.4GHz has better wall penetration and coverage area, while 5GHz is less congested and has higher throughput at smaller distances.

Bandwidth Capability: (20MHz, or 20/40MHz) Specifies whether the adapter should use 20MHz wide channels only, or allow for 40MHz channels if there is no interference. Generally, this should be set to 20/40MHz to allow for higher throughput.

Beamforming: an important MIMO companion, enabling considerable improvement in 802.11n/ac performance, reliability, range and throughput. It should be enabled, if available.

Bluetooth Collaboration: minimizes interference with Bluetooth devices by enabling I/O transmit suppression protocol.

Channel Width: Controls the width of the channel (20 or 40MHz) used by the AP to communicate with client devices. Recommended «Auto (AP determines width)» if available for pure throughput. Setting this to 40MHz-only mode may prevent older clients from connecting.

D2 Listen Interval: similar technique to «Assoc Listen Interval», use values between 3-7. In general, higher beacon periods and DTIM intervals in wireless networks allow for better battery life, however, data has to be buffered at the AP between DTIM beacons, which may be undesirable for VoIP/gaming.

Fat Channel Intolerant: 802.11n setting, recommended «Disabled» for pure throughput.

Fragmentation Threshold: Specifies the maximum number of bytes a packet can contain before it is fragmented. Typically, the default value is 2347 bytes and should be left alone, unless there is a high number of collisions and/or interference.

Global BG scan blocking: By default, the Wi-Fi adapter performs periodic scan for other available Access Points. Disabling this behavior can be helpful to avoid some brief connectivity interruptions. Recommended setting it «On good RSSI», possible settings are listed below.
— «Always» setting — will not scan periodically for other available APs.
— «Never» (default) — will perform periodic scans for other APs.
— «On good RSSI» — will only scan for other APs when the current AP’s signal strength is low.

GTK rekeying for WoWLAN: Group Temporal Key (GTK) rekey is used to encrypt/decrypt network traffic Enabled by default.

HT Mode: Allows for choosing which specific wireless modes are supported. High Throughput (802.11n), and/or Very High THroughput (802.11ac).

Intel Throughput Enhancement: Enables Intel packet bursting technology for transmissions. It utilizes either a WMM capable access point, or client enhancements (even without AP support).

LTR Enable/Disable, LTR Active Value: (default = 60 microseconds) Latency Tolerance Reporting (LTR) is a PCI Express power-saving technique allowing the the adapter to specify when it is idle, and maximum latency. LTR is optional.

MIMO Power Save mode: a.k.a. «Spatial Multiplexing Power Save» (SMPS). Allows the client to save power by keeping one antenna in a receive idle state.
— Auto SMPS: the client decides SMPS mode automatically depending on network conditions
— Dynamic SMPS: client keeps only one antenna active. AP must send RTS packet to trigger the client to wake sleeping radios/antenna before sending MIMO packets.
— Static SMPS: client keeps only one antenna active; AP cannot send MIMO packets to the client
— No SMPS: client always keeps all antennas active; AP can send MIMO packets to the client

Minimum Power Consumption: when enabled, the client can turn off the radio or stop scanning for networks when the adapter is not associated with an access point, or when the computer is in idle state. It is useful to enable in many cases.

Mixed mode protection: Avoid data collisions in a mixed 802.11b and 802.11g environments. Not valid when 802.11n only mode is enabled.
— RTS/CTS Enabled (default): allows mixed clients to hear each other.
— CTS-to-self Enabled: allows to gain more throughput where clients are closer.

NS Offload: responds to network discovery when computer is asleep. It should be left enabled in most cases.

Packet Coalescing: Enables power saving by reducing the number of receive interrupts. The setting combines some broadcast or multicast packets. Default is «enabled», setting to «Disabled» may help in some gaming environments.

PLCP Header (BSS PLCP Header): Used to set the header type for CCK (Complimentary Code Keying) rates (long, or auto short/long), only relevant for 802.11b. By default it automatically switches between long and short depending on the situation the card is in. In some environments with older clients it may be necessary to set this to long for backward compatibility.

Power Output: Usually in percentage increments, allows for reducing the transmit power below 100%. Wireless Power outputs that are unnecessarily high may actually degrade performance by introducing additional noise to the area.

Preferred band: In an environment where one band is very noisy (congested by cordless phones, other APs, client devices, microwaves, etc.), one can reduce interference by preferring the 5GHz band over the 2.4GHz band, or the reverse.

Priority & VLAN: By default, packets are send using FiFo (First-in, First-out) regardless of any priority information in the packet. When this is enabled, you can give certain classes of traffic a priority in the queue. This setting is related to WMM/QoS and only useful if one needs to improve throughput of one of the four WMM classes at the expense of other traffic.

Rate: This setting can limit the wireless transmit/receive rate of the network adapter, it should be left at auto in most cases.

Roaming Aggressiveness: Recommended «Medium»

Roaming Decision: Specifies the signal strength when other access points in the area should be considered for connections. This can be lowered to make the client switch access points faster. «Optimize bandwidth», or «Optimize distance» are automatic settings in some Broadcom adapter drivers as well.

Roam Tendency: Specifies how fast the client should switch to a new distant access point, lower values can make the adapter switch faster.

RTS Threshold: Numeric value, typically 2347, range from 0 to 2347. Lowering the RTS Threshold causes the device to use «Request-to-send/Clear-to-send» (RTS/CTS) whenever it sends data, essentially clearing the channel before data is sent. RTS clears the area around the transmitter, and CTS clears the area around the receiver. Lowering the value can sometimes help reduce collisions in very congested Wi-Fi areas (many adapters/APs on the same channel). However lowering RTS/CTS also adds overhead to the channel by increasing the number of packets without data. Only lower in areas with significant interference.

Short GI: Shortening the Guard Interval is a 802.11n standard that specifies shorter delay between transmitted packets and can reduce wireless latency. It should be set to «auto», or «enabled» for 802.11n and newer WLANs.

Transmit Power: Recommended setting to «Highest» unless in a noisy wireless environment.

Throughput Booster/Enhancement: Enhance the transmit throughput by allowing the client Wi-Fi adapter to hold longer possession of the connection than normally to send data to the AP. This only improves upload throughput (from client to the AP) and only useful for uploading large files. It may negatively impact other Wi-Fi clients since only one client can transmit at a time. Recommended setting is «Disabled»

WMM Power Save / U-APSD: WMM-PS allows for power saving with latency-sensitive applications like VoIP. It may also improve their receive (RX) throughput.

WFD Channel Number: Wireless Flash Drive channel number.

WiFi Rekeying Offload (GTK rekeying): Speci fies if the network adapter can offload GTK rekeying tor WoWLAN (Wake on WLAN) when the computer goes to sleep state.

WMM / WME: Wi-Fi Multimedia (WMM), previously known as Wireless Multimedia Extensions (WME) is a wireless quality of service (QoS) standard subset of 802.11e. It prioritizes data packets according to four categories (voice, video, best effort, background) and also features a power save mode. It should only be enabled if needed for power saving or VoIP. It may reduce throughput in some cases.

Xpress Technology: Broadcom adapter specific based on 802.11e and WMM. Aims to improve Wi-Fi network efficiency and boost throughput by repackaging data to reduce overhead. It is only useful for mixed 802.11b/g/n networks, disable for n/ac networks. Also see: What is Xpress Technology

Notes:
Use only the protocols and options that you need with network adapters. For example, you can turn off «QoS Packet Scheduler», «IPv6», etc. if you do not use them.

Some of the advanced network adapter settings above can vary between different models and drivers, and typically not all of them will be available.

If you’re experiencing problems with your network after editing the above settings, you can reset TCP/IP and Winsock, delete and reinstall your Network adapter driver from the Device manager to restore its factory defaults.