Cellular Routers come in many types, with a single 4G modem or with multiple 4G modems. This last type can be either doing Load Balancing or Bonding. The real challenge with cellular routers is actually to get them producing a good send signal that is strong (enough) at the cell tower of the operators.
Cell towers are equipped with large antennas that provide a strong signal and reach quite far. A smartphone or a cellular modem is equipped with a small antenna and produces therefore a very weak signal over a long distance to that cell tower. In urban areas there are enough cell towers in the neighbourhood to connect with but at the countryside or even remote locations cell towers are quite far away. The produced signal level from a cellular modem is not reaching the cell tower or the signal is too bad to distill the data from it. This is the main reason when you phone or modem stops working due to ‘no signal’. The cell tower still can connect to the cellular modem but the modem cannot acknowledge this and than the connection is dropped. Mind it is always about a two way street-like traffic, going up and down.
Than it becomes necessary to use better antennas and/or antenna locations to produce a better signal. But there are physical limits to these methods.
- Place the antenna outside at the highest free line-of-sight position
- Better antennas, longer dipoles or directional antennas
- Use the best possible coax cable, which has the lowest attenuation figures
- Get to know on what frequency band most often a connection is established
- Match this with the attentuation figures of your cable and the amplification figures of your selected antenna.
When all this is being done, you have done all you can to optimize your cellular signal conditions in a passive way (‘Passive’ meaning without the use of amplification electronics). And if this is still not sufficient than you can make use of our…
Cellular Amplifier Combiner.
This is truly a piece of genius high frequency engineering!
This Cellular Amplifier Combiner allows for a maximum of 4 LTE MiMo modem connections to be combined in a 6 band LTE MiMo amplifier with just 1 MiMo LTE external antenna. Quite a mouth full of technical qualifications. Just imagine..
4 LTE MiMo connections equal 8 physical antenna connections. These are fed into an active combiner and then the output is directed to 5 independent selective frequencyband amplifier stages and from there fed into only 1 external antenna.
Just the reduction of all external cabling, 2 compared to 8 cables will become a significant costreduction, often already justifying the application of this amplifier-combiner. This high quality coaxcables don’t come cheap. They need to be carefully installed, no square bending etc. The cables can become quite sturdy and thick which will significantly increase the installation costs. So only the cable reduction and fewer hours needed to do the proper installation equals the costs of this amplifier-combiner. And then we don’t even talk about the signal gains, that will be done in the below chapter.
First, and foremost, this amplifier never exceeds the legal signal limits! As such a mobile operator cannot distinguish this amplifier from any passive setup. What it does, however, is making your external antenna appear as a virtually larger antenna, producing a better signal to the celltower, overcoming the inefficiencies of a smaller or passive antenna setup. The result is just phenomenal!
Cellular Load Balancing Routers or Bonding Routers all utilize multiple cellular modems internally. The reach with an optimized passive antenna setup is often a double of a traditional setup. With our amplifier-combiner this is even quadrupled . Over water,, lakes or seas, we reach till the horizon. That is about 50 km away from the coastline and still capable of doing HD YouTube clips.
On top of that we have an extremely good experience with the quality and reliability of this product. Never one customer complained about the performance nor any product has been returned as defect! Truly a piece of genius high frequency engineering.