Before Wi-Fi really gained traction in the enterprise and education space, planning a wireless installation was a breeze.
We just based everything on coverage. Fast forward to today and it’s crystal clear how critical Wi-Fi has been for productivity, business, and innovation. High-density Wi-Fi is a requirement.
What has changed in the way Wi-Fi has been deployed? Well.. a lot.
Outlined below are best practices for deploying high-density wi-fi for the educational institutions. It’s meant to be more of a guideline in assisting the wireless engineer in their designs for coverage and capacity.
Applications are putting a demand and strain on wireless networks. To provide reliable connectivity we must perform a lot of planning upfront to create a proper design to meet today’s Wi-Fi requirements. After deployment, a validation survey must be performed to find out if any optimization is required.
Wi-Fi is killing you because of these issues:
- Non-existent planning
- Poor designs from guessing
- Poor user experience
- Increased troubleshooting and tickets
Without extensive planning, it will make designing a high-density wireless network a guessing game. A considerable amount of time should be focused on identifying which applications are expected to be used, how many devices will be associated with the Wi-Fi network, and what bandwidth requirements need to be met, etc. There can be a long laundry list of questions.
Poor planning creates a ripple effect which leads to an improper best guess design that negatively affects end-user experience. Not to mention an increase in troubleshooting and escalated tickets.
Below are best practices that should be applied for high density Wi-Fi in Education. This is meant to be a guideline for providing reliable Wi-Fi and is intended to be used for wireless network engineers.
Before configuring any hardware, we must find out what kind of application should the wireless network be designed for? The type of application will tell what kind of throughput needs to be supported.
The application throughput is then applied to the number of devices expected to be using Wi-Fi.
We can use application throughput requirements and the number of devices to come up with an approximate number of required radios.
Other requirements include aesthetics, coverage areas, and more, including the categories listed below.
Disable legacy data rates and select your basic data rates to create smaller cell sizes. A word of caution with disabling low data rates – legacy devices will not be able to join the BSS.
Another reason for disabling low data rates is to allow the newer devices to take advantage of the network by spending less time transmitting over the air.
As devices get farther from an access point, they will dynamically drop to a lower data rate and less complex modulation. Using higher data rates can “push” the device to roam to a neighboring access point.
Channel Re-Use Plan
The 2.4 GHz band only has three non-overlapping channels. That is not much to use in a high-density environment. Design a network with 5 GHz in mind. Even if you plan to lower the transmit power of a 2.4 GHz radio it still propagates far distances, especially with lower data rates enabled.
The 5 GHz band provides 25 channels to reuse. With a sound channel plan, you avoid the co-channel and adjacent channel interference.
More channels provide you with separate contention domains to assist devices in spending less air time transmitting and receiving data.
The use of 20 MHz channels is a must. Earlier I mentioned the channel re-use plan. That channel re-use plan for 5 GHz is ideally positioned for high density in co-working spaces, enterprises and pretty much any time your site survey shows more than one or two other APs on 5GHz.
While 40 MHz channel widths give you larger data rates, be sure to verify the amount of channel overlap as to not cause contention domain issues.
Do not ever use 80 or 160 MHz channels in a high-density environment. There are not enough channels to reuse with this configuration.
An important goal in high-density Wi-Fi for education is the creation of contention domains. The channel re-use plan will be vital in the design of contention domains.
The network can operate more efficiently with smaller contention domains. This is achieved by getting devices off the air as soon as possible.
Take a lecture hall with three sections of seats to fit 200 people as an example. One access point may be able to provide sufficient signal for the lecture hall. But the real question is will it meet capacity needs.
If the professor has every student download a large video there will be 200 devices contending for air time to download this video. That’s one dual-band access point reaching capacity.
We can create multiple contention domains by adding an access point to service each section, using directional antennas. This splits the devices onto different radios. The result is faster transmissions for devices and less air time spent communicating on the medium.
Omnidirectional antennas propagate signals in a 360-degree radius. When a high-density environment requires many access points to meet requirements we receive a lot of RF from each access point.
This can lead to CCI and ACI. Although transmit power settings can be tuned, an omnidirectional signal can propagate far in an open space.
Use directional antennas to form smaller, specific, cell sizes. An antenna with a narrow beam can effectively cover a section and still provide overlap for a non-overlapping cell.
Directional antennas provide a method of limiting CCI and ACI between access points.
An example of directional antennas are patch or yagi antennas.
A predictive site survey can be a time saving way to come up with a design based on gathered requirements. The purpose is to predict signal propagation, coverage, and capacity.
It can be an alternative to an on-site AP-on-a-stick survey or can be an augment to it.
The AP-on-a-stick survey may be more accurate than a predictive survey but will require more time.
If time is a concern, a predictive survey will help eliminate the guessing game of designing a wireless network.