Dubbed BaiEPC, the solution will be available in two forms – Standard and Professional. The Standard version is designed for small to mid-sized networks, while the Professional version is designed for larger networks and provides smaller companies an expansion path as their businesses grow.
Traditional hangers and diameter-specific grommet combinations complicate installations, making it difficult to secure cables from wind and vibration, which can cause passive intermodulation (PIM) problems.
Check out PIM hangers from Tessco.
-450M is the 3GHZ platform of today.
-LTE will be a split architecture system
-Working on the ability to swap out an existing AP from another manufacturer and still keep the subscribers.
-450 is still going to outperform LTE in many ways
-8×8 Baseband unit (BBU) and Remote Radio Heads (RRH)
-BBU can drive 4 2×2 radios to provide 350 degree coverage
-One radio for a single Sector MU-MIMO support
-Fiber optic connection between BBU and RRH
-Release of 3.xGHZ in Q2 2019 is the goal
-64 SMs per sector initial
-2x Gige ports in the BBU
-Possibility and possibility is stressed, that 450 3ghz subscribers might be able to connect to the new platform.
-Sim cards are aiming to be built in.
Full site approximate price for a complete build for $15,000.
Things could change
Recently, we had a client question why we didn’t mount antennas higher up on a tower with an FM repeater on it. The top of the tower has an FM repeater on it so we mounted the equipment about 25 feet below that.
When you are talking about antennas and transmitters the basic thing to remember is it’s all radiation. Good antennas have predictable drop off patterns and, when paired with a good transmitter, have crisp frequency drop offs. However, there is still radiation emitting from feedline and the antenna on the tower. Many FM repeaters use a dipole design. Some are folded, others are different types. Below is an antenna pattern from a Dipole antenna.
As you can see there are a few patterns radiating from the antenna. These patterns should be taken into consideration when mounting your equipment near FM, UHF, or VHF systems. Radiation may interfere with things such as your cat-5, or your PIM. In an earlier article, I talk about low-pim cables and what affects PIM. This is very important when you are deploying LTE gear. RF radiation from high power transmitters can cause PIM issues if the wavelength happens to coincide with the wavelength of the other transmitter. This does not mean they are on the same frequency. Remember, in RF you have full wave, 3/4,1/2, and 1/4 wavelengths to deal with.
Other things to consider are near and far field patterns. If you want some heavy reading you can read about it on Wikipedia.
Our next issue and the most common issue is the radiation getting into our Ethernet cables as well as our radios on the tower. Below illustrates the propagation of signals coming out of an antenna on the top of the tower. If you notice, some of the radiation is directed underneath of the antenna. Any equipment mounted too close underneath will be bombarded with radiation.
Too much radiation can cause link negotiation issues, signal degradation, and other issues. By moving our antennas out of the patterns of other antennas we can make for a more reliable system. This is one case where higher on the tower is not always better. Just because another antenna is not mounted in front of another it does not mean they are in each other’s radiated patterns.
As the number of WISP LTE deployments increase, there are many things WISPs will need to be mindful of. One such item is properly supporting antenna cables. LTE systems are more sensitive to cable issues. In a previous blog post, I talked about pim and low-pim cables. One of the things that can cause low pim is improperly mated cables. If cables are not supported they can become loose over time. Vibration from equipment or even the wind can loosen connections.
How do we support cables?
We can take a cue from the cellular industry. The following are some examples of proper cable support. Thanks to Joshua Powell for these pics.
Where can you get these?
A good place to start are sites like sitepro1 or Tessco has a selection.
So the next time you are planning your LTE deployment think about cable support.
One of the topics that came up during the Baicells troubleshooting tips was the notion of PIM testing, and cables which are PIM rated.
PIM sweeps are a common thing in the Cellular field. One of the first questions folks often ask is what is a PIM sweep? If you think of PIM testing as a passive test and line sweeping as an active test that is a good start. PIM testing looks for problems with things like connectors, cables, and other “layer 1” items. A PIM test is not a line sweep. Line sweeping measures the signal losses and reflections of the transmission system. this is typically VSWR. A line sweep is an active test. It can not detect the same things a PIM test can. Many HAM radio folks are familiar with a line sweep where the reflected power is measure in an antenna system. In a line sweep you deal with reflected power and all that.
What does a PIM test do?
When you do a PIM test typical two high power signals are injected into the antenna line. You can actually pass a sweep test but not a PIM test.
I won’t go into PIM tests very much because you need high dollar units such as those from Anritsu and Kaelus. These cost 10’s of thousands of dollars new. Sometimes you can find these used. However, the next thing you will run into is understanding the output of such a device. Cell crews go to week long certification classes to become a PIM certified tech from Anritsu and others.
What causes a PIM test to fail?
According to Kaelus the most common problems are:
• Contaminated surfaces or contacts due to dirt, dust, moisture or oxidation.
• Loose mechanical junctions due to inadequate torque, poor alignment or poorly prepared contact surfaces.
• Loose mechanical junctions caused transportation shock or vibration .
• Metal flakes or shavings inside RF connections.
• Poorly prepared RF connections
•Trapped dielectric materials (adhesives, foam, etc.)
•Cracks or distortions at the end of the outer conductor of coaxial cables caused by over tightening the back nut during installation.
• Solid inner conductors distorted in the preparation process causing these to be out of round or tapered over the mating length.
• Hollow inner conductors excessively enlarged or made oval during the preparation process.
Why does cable matter?
Cables do not typically cause PIM, but poorly terminated or damaged cables can and do cause problems.
Cables with Seams can cause issues. The seam can corrode. Plated copper, found in cheaper cables, can break away from the aluminum core. This actually allows small amounts of flaking to happen between the connector and the core of the cable. This will cause PIM issues and is very hard to diagnose. Imagine little flakes inside a connector. You don’t see them until you break open the connector, and even then they may be pretty little flakes.
Cables can change their physical configuration as temperature varies. For instance, sunshine can warm cables, changing their electrical length. A cable that happens to be the right length to cancel out PIM when cool may show strong PIM after changing its length on a warm day, or, it can work the other way around, good when hot and bad when cold. In addition, the physical change in length can make a formerly good connection into a poor one, also generating PIM. Other environmental factors such as water in the connector or cable can be an issue, as with any RF setup.
I think I have PIM issues. What are some indications?
PIM often shows up as poor statistics from the affected antenna. One of the first and most direct indications of PIM can be seen in cells with two receive paths. If the noise floor is not equal between the two paths, the cause is likely PIM generated inside the noisy receive path.
How Do I prevent PIM issues?
Cable quality and connector quality are one of the biggest factors in the PIM quality of a LTE system. Many WISPs are used to making their own LMR cables and putting on their own connectors. There is a difference between a low PIM LMR-400 cable and normal LMR-400. Same for connectors. One of the recommendations today was to use 1/2” superflex heliax.
The easy recommendation is to buy pre-made cables that have already been PIM certified. In a typical WISP setup, you do not have lots and lot of components in your setup. Buy already certified components from your distributors that are “Low PIM rated”.