Wireless is seeing remarkable annual increases in usage. While this happens, more and more wireless terminology is being used to describe the standards, technology, providers and products that support it.
As these terms are used, there’s been some confusion in the industry. (What’s the real difference between LTE and LTE Advanced? How are MIMO and massive MIMO different?) To make things easier, we’ve created a two-part blog to cover some of the common wireless terminology we use and hear every day.
In this first blog, you’ll find wireless terminology that’s specific to technology, speeds and standards. In next week’s blog, you’ll find more product-specific wireless terminology. Consider this your go-to wireless terminology guide.
As the next-generation wireless technology released after 3G, 4G is a fourth-generation mobile communications standard released in 2008 that features faster upload and download speeds than 3G. Sometimes 4G and LTE are used together; sometimes they are separated. True 4G speeds (100 Mb/s download speeds) can only be achieved with LTE.
This fifth-generation wireless technology began to roll out in 2019 and offers the ability to customize services to customers with either increased bandwidth, density and speeds or lower latency as compared to 4G. It’s designed to support technology like IoT, enhanced mobile broadband and autonomous vehicles. It’s one of the most-used wireless terminology phrases we hear right now.
5G NR (5G New Radio)
Designed by 3GPP (3rd Generation Partnership Project), 5G NR is a new radio access technology that serves as the global standard for the air interface of 5G networks. When combined with LTE Pro, 5G NR will be able to deliver on any of the 5G initiatives.
Another word to describe a mobile network provider, such as AT&T, Verizon, Sprint or T-Mobile.
CBRS (Citizens Broadband Radio Service)
Sometimes referred to as Private LTE, CBRS is an increasingly popular, in-building wireless technology that operates on a shared spectrum in the 3.5 GHz range, which, up until recently, was dedicated solely to the U.S. Navy.
By decentralizing data processing and bringing it closer to the location or device that needs or wants to consume it, edge computing improves response times and reduces latency. This enables technology like mobile computing and IoT.
Gb/s (or Gbps)
A data speed that represents gigabits (or billions of bits) per second.
LAA (Licensed Assisted Access)
A feature of LTE Advanced Pro that can use unlicensed 5 GHz band combined with licensed spectrum to boost performance. LAA shares the same spectrum as Wi-Fi, so it’s important to avoid channels being used by Wi-Fi. To do this, LAA uses Listen-Before-Talk (LBT) technology to determine whether a channel is currently being used by Wi-Fi.
LTE (Long-Term Evolution)
A wireless standard for wireless broadband communication in mobile devices and data terminals, LTE is based on GSM/EDGE and UMTS/HSPA technologies. It provided a path to achieve 4G.
LTE Advanced (LTE-A)
This mobile communication standard is an enhancement of LTE. It provides higher performance and data rates than 4G LTE (1 Gb/s vs. 100 Mb/s download speeds) via carrier aggregation, which combines bandwidth across multiple frequencies. LTE-A is standardized by 3GPP specifications with Releases 10, 11 and 12.
LTE Advanced Pro (LTE-A Pro)
This next-generation release came after LTE Advanced and is based on 3GPP specification (Releases 13 and 14). It offers a data rate of >3 Gb/s, using licensed (400 MHz to 3.8 GHz) and unlicensed (5 GHz) spectrums. LTE-A Pro provides a cost-effective option to support IoT and is considered an intermediate step to 5G.
Massive MIMO groups antennas together (at least 64 [8x8] antennas) at transmitters and receivers for better throughput and efficiency. The more antennas there are, the more possible signal paths there are, resulting in improved coverage, higher capacity and reliability. Massive MIMO is considered a core component of 5G networks.
Mb/s (or Mbps)
A data speed that represents megabits (or millions of bits) per second.
MIMO (Multiple Input Multiple Output)
MIMO is RF technology that uses multiple antennas and multi-path propagation to increase robustness and throughput. It sends and receives more than one data signal simultaneously over the same radio channel by exploiting multipath propagation.
PIM (Passive Intermodulation)
A type of interference, PIM is a critical characteristic of components, including cable assemblies and connectivity used in a wireless RF (radio frequency) system. High PIM can result in unwanted noise at the same frequencies as a carrier’s transmit or receive signals. Because this noise can lower the signal to noise ratio, the results can be slow data, poor connections and even dropped calls.
RF (Radio Frequency)
An electromagnetic signal used to transmit wireless signals.
A term to describe the provider of wireless connectivity solutions, such as DAS, Wi-Fi and small cells. Providers build wireless networks, provide wireless products and services, and acquire long-term wireless rights at stadiums, transportation hubs, universities, offices and convention centers.
VSWR (Voltage Standing Wave Ratio)
A ratio of the signal and reflections maximum adding (in phase) and subtracting (out of phase). It’s a key coax electrical parameter to determine DAS performance (low VSWR is good and high VSWR is bad). VSWR is mathematically equivalent to return loss. (For reference, a VSWR of 1.15 is the same as a return loss of -23.1 dB.)
This next-generation wireless technology is also known as 802.11ax. Wi-Fi 6 supersedes 802.11ac or Wi-Fi 5. It provides better Wi-Fi performance in device-crowded environments, has faster speeds and is expected to have the ability to connect directly to the central network core. It operates in the 2.4 GHz and 5 GHz bands. Certification began in September 2019.
A new terminology for devices that will offer the features and capabilities of Wi-Fi 6 extended into the 6 GHz band.
Ron joined Belden in 2016 to help define the roadmap of technology and applications in enterprise. Prior to this, he developed cables and connectivity for Panduit and Andrew Corp. Ron Tellas is a subject-matter expert in RF design and Electromagnetic Propagation. He represents Belden in the ISO WG3 committee, TIA TR42 Premises Cabling Standards, IEEE 802.3 Ethernet Working Group and is a committee member of NFPA 70 Code-Making Panel 3. Ron is the inventor of 16 US patents. He has a Bachelor of Science degree in Electrical Engineering from Purdue University, a Master of Science degree in Electrical Engineering from Illinois Institute of Technology, and a Master of Business Administration from Purdue University.