INDUSTRIAL ROUTER CPE: An Incredibly Easy Method That Works For All
AD7028 IEC101 5G router is your enabler whether you're looking for secure remote maintenance solutions or want to link your manufacturing floor with maximum bandwidths for data-intensive applications. It offers all the 5G functionalities listed in Release 15 of the standard.

The wait for 5G performance is over

Many applications across various industries can be accelerated by Industrial 5G Router CPE. Therefore, our AD7028 IEC101 5G router is your enabler whether you're looking for secure remote maintenance solutions or want to link your manufacturing floor with maximum bandwidths for data-intensive applications. It offers all the 5G functionalities listed in Release 15 of the standard.

With 5G, a new mobile communications standard that considered industrial use cases was created for the first time and is already being implemented. Enhanced Mobile Broadband (eMBB), Ultra-Reliable Low-Latency Communications (URLLC), and Massive Machine-Type Communications are the three basic 5G scenarios (mMTC). Both eMBB and URLLC satisfy the requirements of industrial IoT applications, such as low latency with best-possible dependability, while serving distinct application domains.


The fifth-generation (5G) technological standard for broadband cellular networks, which cellular phone providers started rolling out worldwide in 2019, is the anticipated replacement for the 4G networks that link the majority of modern cell phones. According to the GSM Association, more than 1.7 billion people will be using 5G networks globally by 2025.

5G networks, like its forerunners, are cellular networks in which the service area is segmented into discrete regions known as cells. Through a local antenna within the cell, all 5G wireless devices are connected to the Internet and phone network via radio waves.

Higher download accelerates to 10 gigabits per second (Gbit/s)—are possible on the new networks. The quality of Internet services in crowded environments is improved by 5G because it is faster than current networks and has a bigger bandwidth that can link more hardware components. The networks are anticipated to be used more frequently as general internet service providers (ISPs) for laptops and desktop computers, competing with current ISPs like cable internet, and will also enable new applications in the internet of things (IoT) and machine-to-machine (M2M) spaces. Because they are not backward compatible with 4G, smartphones with only 4G capabilities cannot access 5G networks.



Depending on the RF channel and BS load, 5G speeds will be in the 50 Mbps to 1 Gbps range. The mmWave bands would have the fastest 5G speeds, reaching 4 Gbit/s with carrier aggregation and MIMO (assuming a perfect channel and no other BS load).


The ideal "air latency" for 5G is around 8 and 12 milliseconds, eliminating HARQ retransmissions and other delays. For proper comparisons, "air latency" must be increased by broadband latency to the server and retransmission latency. According to Verizon, the 5G early deployment's latency is 30 ms. The latency may likely be reduced to 10 to 15 ms by edge servers located near the towers.

Error rate

In order to achieve a much low bit error rate (BLER), 5G uses adaptive modulation and coding strategy (MCS). A lower MCS, which is less error-prone, will be used by the transmitter whenever the error rate exceeds a (very low) threshold. Speed is traded in this way to guarantee nearly error-free service.


Transmit power, frequency, and interference are just a few of the variables that affect 5G's range. For instance, mmWave will have a lower range than mid-band (such as the n78 band) which will have a lower range than low-band (for example, the n256 band) (e.g.: n5 band).

Applications requiring little power usage and having a lot of connected devices employ MMTC. However, it is not feasible to implement all three of these major scenarios simultaneously within the same network. There is just one scenario that a network can be fully configured to accommodate. For instance, it can provide either the fastest data throughput or the shortest latency. It is impossible to do both at once.

This is where the need for various 5G network implementation strategies comes into play. A public 5G network is often designed to offer large bandwidths for data-intensive applications like video telephone and streaming video.

High bandwidth is a major selling point for mobile service providers that are currently deploying 5G in a number of nations worldwide.

A vital foundation for remote access and remote maintenance solutions is provided by public 5G networks. The flexibility of the technology, which is a key component of the standard, is where 5G has an edge. For instance, with small radio cells and high frequencies, consumers in urban areas can access very high bandwidths. Lower frequencies are used and more users share the available bandwidth in rural locations since radio cells must cover a broader area.

Industrial 5G Our commitment to the future.

New ideas and technology are necessary for manufacturing, intralogistics, and transportation before the smart factory can be approved. Applications including mobile robots in manufacturing, autonomous vehicles in the logistics and transportation industries, the IIoT, augmented reality applications for service and maintenance specialists, and virtual reality applications for users are already being discussed. But each of these uses places pressure on the network that would quickly exhaust it. Industrial 5G's unmatched dependability, incredibly low latencies, and extensive IIoT connectivity can pave the way for ground-breaking applications in the industrial setting.


In our search for long-term, sustainable communication solutions, we are developing an Industrial 5G ecosystem that consists of a private 5G infrastructure and end devices.