OPINION: You Really SHOULD Consider Using Wireless for Your Industrial Edge!

Conventional wisdom says that wired networking, such as Ethernet, is the right choice for most industrial connectivity.

However, wireless networking has several advantages over wired networking:

• Infrastructure costs may be less since no or fewer wires need to be installed.
• There is a lower chance of downtime from damaged wires.
• Equipment can be more easily moved and placed with more flexibility.
• Some applications, like autonomous robots and mobile handheld devices, simply cannot have a wire attached.

The main reasons normally given for why wired networking is preferred are:

• Reliability – wired networking’s resilience against electromagnetic (EM) interference and contention from other devices.
• Consistency – wired networking is assumed to be the only way to get more consistent bandwidth, low latency and prioritization for critical connections.

In this b log, we will see that wireless connectivity has advanced quite a bit recently to make it a real contender to be considered for your industrial edge application.

Wireless Technology – The Earlier Years

It has been more than 20 years since I was first introduced to Wi-Fi. 802.11b had just become available, offering a “blistering” 11 Mbps, if you were lucky. I was an early adopter and had proudly bought an SMC Wi-Fi PC Card.

No one I knew had a Wi-Fi access point at home nor did they have Wi-Fi on their laptops. I was able to walk from the bedroom to the living room and still go online, albeit slower than what we are used to today. You had to be careful how many walls were between the laptop and the access point. Turning on a microwave oven could drastically (negatively) affect your Wi-Fi network.

I had also just bought myself a Nokia candy bar-style cell phone that ran on 2.5G cellular technology. Digital cell connections were not as widespread and I insisted on having an analog backup, known as Advanced Mobile Phone System (AMPS), on my phones for better coverage. You were happy to have enough bars to receive any phone calls.

Wireless Technology Today

Fast forward to today and we see that speeds have gone up, latencies have dropped, more spectrum is available and technology has drastically improved. Engineers have learned from past deficiencies and inefficiencies of wireless technology and solved for many of them in current standards.

Here is a table that shows just how dramatic some of those improvements are, even recently.

In the past 7-9 years:

• Peak bandwidth has increased by 5-100X.
• Typical latency has dropped by 2-50X.
• New frequency bands are now supported that help address contention and offer tradeoffs between distance and speed.

The latest standards for wireless networking today are: Wi-Fi 6E and 5G.

While many different improvements are responsible for where Wi-Fi 6E and 5G are today, I want to focus on a few of the more impactful improvements that help address concerns about using wireless networking in industrial edge applications:

• Time-Sensitive Networking
• OFDMA
• Additional Frequency Bands

Time-Sensitive Networking – Extending Determinism To Wireless Networks

Time-Sensitive Networking (TSN) started off as a set of networking protocols and standards developed by the IEEE 802.1 TSN working group and was initially implemented for Ethernet wired networking. TSN’s purpose is to make networks that are originally best-effort and make them more deterministic. Deterministic networking means that packets are delivered in a reliable, specific and predictable period of time, not faster or slower. This property can be critical in certain industrial edge applications, such as machine control and safety.

Implementing TSN on wireless is inherently challenging since the capacity and reliability of those links can change depending on environmental conditions, such as interference, attenuation and other devices. However, the IEEE 802.1 TSN working group has recently extended TSN to work on Wi-Fi.

The 3rd Generation Partnership Project (3GPP) has created a similar standard as a part of the 5G network architecture, called Ultra-Reliable Low Latency Communications (URLLC). URLLC allows for more efficient scheduling of data transfers, provides for shorter transmissions and the potential for overlapping transmissions. The aim of URLLC is to provide high 5G network reliability and extremely low latencies of approximately 1 ms for data transmissions.

Both wireless TSN and URLLC significantly improve the reliability and latency of Wi-Fi and 5G to unprecedented levels, eliminating previous barriers to use wireless networking in industrial edge applications that needed these properties. With standards and appropriate bridging, this determinism can also be guaranteed across heterogeneous networks of both wired and wireless technologies.

OFDMA – It’s All About Efficiency, Resilience and Lower Latency

In wireless networking, radio spectrum is a scarce resource and finding ways to make more efficient use of that spectrum is key to improving wireless technology. The primary technique used is Orthogonal Frequency Division Multiplexing (OFDM). Before OFDM, Frequency Division Multiplexing (FDM) and Time Division Multiplexing (TDM) were used. FDM requires that channels be divided into separate frequencies that do not overlap and have guard bands that interference and crosstalk. While simpler to implement, this is not a very efficient use of spectrum and is only used when the usable bandwidth in the channel is more than what the application needed. TDM requires that each device be allocated a specific time slot when it can communicate. This is also not very efficient since, if a device has no data to send, it is possible to have time slots when the channel is not used at all.

OFDM, first introduced in 802.11a, subdivides a channel into smaller channels. Signal frequencies are allowed to overlap if they are placed at the exact right spots. The math behind OFDM is outside of the scope of this blog but the result is much more efficient use of the wireless spectrum.

Another benefit, beyond spectral efficiency, of OFDM is resilience against EM interference. EM interference may not affect all subchannels equally. By sending data over multiple subchannels, devices can avoid noisier subchannels to maintain a more reliable link.

While spectral efficiency and reliability is achieved with OFDM, it still only allows communication between the access point and a single client device at a time. As the number of client devices increases in a wireless network, the overall latency will increase as clients would need to take turns with the shared channel.

In W-Fi 6, Orthogonal Frequency Division Multiple Access (OFDMA) was introduced which allows communication with more than one device at the same time. The way this is accomplished is by assigning certain subchannels to different devices instead of allocating all the subchannels to a single device during a transmission. The result is that more than one device can communicate at the same time. This has significant benefits to average latency and prioritization. Devices that require lower latency or guaranteed performance can be given priority in subchannel assignments.

OFDMA is also used in 5G to improve efficiency and lower latency.

Additional Frequency Bands – Picking The One That’s Right For Your Application

As Wi-Fi has become more popular, so have the number of devices that use it to communicate.

2.4 GHz, which is the original frequency band for Wi-Fi, is often very crowded with not only commercial devices but also personal devices that employees bring with them from home. Many other wireless devices, including Bluetooth, operate in that same unlicensed band.

802.11a added the 5 GHz band which offers more spectrum, less contention, less interference and higher bandwidths. Over time, this band has become more popular, once again leading to potential contention issues.

With Wi-Fi 6E, you now have the option to use the 6 GHz band (where available by regulation), which offers even more spectrum for higher bandwidths. More importantly, with the lack of legacy Wi-Fi devices in this new band, industrial edge devices will experience less contention, leading to potentially more reliability and lower latencies.

There is a tradeoff as you use higher frequency bands. As you move up in frequency, range decreases as the signal is attenuated as it passes through objects and walls. However, with Wi-Fi 6E, you can choose the frequency band that is right for your industrial edge application.

5G offers not only more spectrum by also a choice based on application. 5G spectrum is divided into 2 frequency ranges:

• FR1 (< 7 GHz): Frequencies in this range will have more range due to less attenuation. It is expected that more traditional cellular communication will be carried in this range.
• FR2 (mmWave): Frequencies in this range will have shorter range but offer higher bandwidth. It is expected that 5G’s promise of much higher speed data will be provided in this range.

The Future Is Bright For Wireless Connectivity At The Edge

As you can see, there have been significant improvements in wireless networking that have helped it overcome many of the past challenges to using it in the industrial edge.

I challenge you to take another look at using wireless for your industrial edge applications, not just as a nice-to-have, but as a core component of your solution.

With all of the advancements in wireless technology, let’s change the question from “why should I use wireless” to “why am I not ALREADY using wireless?”

Share your thoughts and experiences.

Credits/Acknowledgements:

• SMC2635W 801.11b Wireless Cardbus image from https://www.amazon.com/SMC-SMC2635W-802-11b-Wireless-Cardbus/dp/B00009L7MO
• Nokia cell phone image from https://www.ebay.com/itm/234093845696