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Tilts
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ALL ABOUT TILTS
What is Antenna Electrical and Mechanical Tilt (and How to
use it)?
The efficiency of a cellular network depends of its correct configuration and adjustment of
radiant systems: their transmit and receive antennas.
And one of the more important system optimizations task is based on correct adjusting tilts, or
the inclination of the antenna in relation to an axis. With the tilt, we direct irradiation further
down (or higher), concentrating the energy in the new desired direction.
When the antenna is tilted down, we 'downtilt', which is the most common use. If the inclination
is up (very rare and extreme cases), we call 'uptilt'.
Note: for this reason, when we refer to tilt in this tutorial this means we're talking about
'downtilt'. When we need to talk about 'uptilt' we'll use this nomenclature, explicitly.
The tilt is used when we want to reduce interference and/or coverage in some specific areas,
having each cell to meet only its designed area.
Antenna Radiation Diagram
The antenna irradiation diagram is a graphical representation of how the signal is spread through
that antenna, in all directions.
It is easier to understand by seeing an example of a 3D diagram of an antenna (in this case, a
directional antenna with horizontal beamwidth of 65 degrees).
The representation shows, in a simplified form, the gain of the signal on each of these directions.
From the center point of the X, Y and Z axis, we have the gain in all directions.
If you look at the diagram of antenna 'from above', and also 'aside', we would see something like
the one shown below.
These are the Horizontal (viewed from above) and Vertical (viewed from the side) diagrams of
the antenna.
But while this visualization is good to understand the subject, in practice do not work with the
3D diagrams, but with the 2D representation.
So, the same antenna we have above may be represented as follows.
Usually the diagrams have rows and numbers to help us verify the exact 'behavior' in each of the
directions.
The 'straight lines' tells us the direction (azimuth) – as the numbers 0, 90, 180 and 270 in
the figures above.
And the 'curves' or 'circles' tells us the gain in that direction (for example, the larger circle
tells you where the antenna achieves a gain of 15 db).
According to the applied tilt, we'll have a different modified diagram, i.e. we affect the coverage
area. For example, if we apply an electrical tilt of 10 degrees to antenna shown above, its
diagrams are as shown below.
The most important here is to understand this 'concept', and be able to imagine how would the
3D model be, a combination of its Horizontal and Vertical diagrams.
what is Tilt?
The tilt represents the inclination or angle of the antenna to its axis.
As we have seen, when we apply a tilt, we change the antenna radiation diagram.
For a standard antenna, without Tilt, the diagram is formed as we see in the following figure.
There are two possible types of Tilt (which can be applied together): the electrical Tilt and
Mechanical Tilt.
The mechanical tilt is very easy to be understood: tilting the antenna, through specific
accessories on its bracket, without changing the phase of the input signal, the diagram (and
consequently the signal propagation directions) is modified.
And for the electrical tilt, the modification of the diagram is obtained by changing the
characteristics of signal phase of each element of the antenna, as seen below.
Note: the electrical tilt can have a fixed value, or can be variable, usually adjusted through an
accessory such as a rod or bolt with markings. This adjustment can be either manual or remote,
in the latter case being known as 'RET' (Remote Electrical Tilt) – usually a small engine
connected to the screw stem/regulator that does the job of adjusting the tilt.
With no doubt the best option is to use antennas with variable electrical tilt AND remote
adjustment possibility, because it gives much more flexibility and ease to the optimizer.
However these solutions are usually more expensive, and therefore the antennas with manual
variable electrical tilt option are more common.
So, if you don't have the budget for antennas with RET, choose at least antennas with manual but
'variable' electrical tilt – only when you have no choice/options, choose antennas with fixed
electrical tilt.
Changes in Radiation diagrams: depends on the Tilt Type
We have already seen that when we apply a tilt (electrical or mechanical) to an antenna, we have
change of signal propagation, because we change the 3D diagram as discussed earlier.
But this variation is also different depending on the type of electrical or mechanical tilt.
Therefore, it is very important to understand how the irradiated signal is affected in each case.
To explain these effects through calculations and definitions of db, null and gains on the diagram
is possible. But the following figures shows it in a a much more simplified way, as horizontal
beamwidth behaves when we apply electrical and mechanical tilt to an antenna.
See how is the Horizontal Irradiation Diagram for an antenna with horizontal beamwidth of 90
degrees.
Of course, depending on the horizontal beamwidth, we'll have other figures. But the idea, or the
'behavior' is the same. Below, we have the same result for an antenna with horizontal beamwidth
of 65 degrees.
Our goal it that with the pictures above you can understand how each type of tilt affects the end
result in coverage – one of the most important goals of this tutorial.
But the best way to verify this concept in practice is by checking the final coverage that each one
produces.
To do this, then let's take as a reference a simple 'coverage prediction' of a sample cell. (These
results could also be obtained from detailed Drive Test measurements in the cell region).
Then we will generate 2 more predictions: the first with electrical tilt = 8 degrees (and no
mechanical tilt). And the second with only mechanical of 8 degrees.
Analyzing the diagrams for both types of tilt, as well as the results of the predictions (these
results also can also be proven by drive test measures) we find that:
With the mechanical tilt, the coverage area is reduced in central direction, but the coverage
area in side directions are increased.
With the electrical tilt, the coverage area suffers a uniform reduction in the direction of the
antenna azimuth, that is, the gain is reduced uniformly.
Conclusion: the advantages of one tilt type to another tilt type are very based on its application –
when one of the above two result is desired/required.
But in General, the basic concept of tilt is that when we apply the tilt to an antenna, we improve
the signal in areas close to the site, and reduced the coverage in more remote locations. In other
words, when we're adjusting the tilt we seek a signal as strong as possible in areas of interest
(where the traffic must be), and similarly, a signal the weakest as possible beyond the borders of
the cell.
Of course everything depends on the 'variables' involved as tilt angle, height and type of antenna
and also of topography and existing obstacles.
Roughly, but that can be used in practice, the tilt angles can be estimated through simple
calculation of the vertical angle between the antenna and the area of interest.
In other words, we chose a tilt angle in such a way that the desired coverage areas are in the
direction of vertical diagram.
It is important to compare:
the antenna angle toward the area of interest;
the antenna vertical diagram.
We must also take into account the antenna nulls. These null points in antenna diagrams should
not be targeted to important areas.
As basic formula, we have:
Angle = ArcTAN (Height / Distance)
Note: the height and distance must be in the same measurement units.
Recommendations
The main recommendation to be followed when applying tilts, is to use it with caution.
Although the tilt can reduce interference, it can also reduce coverage, especially in indoor
locations.
So, calculations (and measurements) must be made to predict (and check) the results, and if that
means coverage loss, we should re-evaluate the tilt.
It is a good practice to define some 'same' typical values (default) of tilt to be applied on the
network cells, varying only based on region, cell size, and antennas heights and types.
It is recommended not to use too aggressive values: it is better to start with a small tilt in all
cells, and then go making any adjustments as needed to improve coverage/interference.
When using mechanical tilt, remember that the horizontal beamwidth is wider to the
antenna sides, which can represent a problem in C/I ratio in the coverage of neighboring
cells.
Always make a local verification, after changing any tilt, by less than it has been. This means
assessing the coverage and quality in the area of the changed cell, and also in the affected region.
Always remember that a problem may have been solved ... but another may have arisen!
Practical Values
As we can see, there's not a 'rule', or default value for all the tilts of a network.
But considering the most values found in field, reasonable values are:
15 dBi gain: default tilt between 7 and 8 degrees (being 8 degrees to smaller cells).
18 dBi gain: default tilt between 3.5 and 4 degrees (again, being 4 degrees to smaller
cells).
These values have tipically 3 to 5 dB of loss on the horizon.
Note: the default tilt is slightly larger in smaller cells because these are cells are in dense areas,
and a slightly smaller coverage loss won't have as much effect as in larger cells. And in cases of
very small cells, the tilt is practically mandatory – otherwise we run the risk of creating very
poor coverage areas on its edges due to antenna nulls.
It is easier to control a network when all cells have approximately the same value on almost all
antennas: with a small value or even without tilt applied to all cells, we have an almost negligible
coverage loss, and a good C/I level.
Thus, we can worry about - and focus - only on the more problematic cells.
When you apply tilts in antennas, make in a structured manner, for example with steps of 2 or 3
degrees – document it and also let your team know this steps.
As already mentioned, the mechanical tilt is often changed through the adjust of mechanical
devices (1) and (2) that fixes the antennas to brackets.
And the electrical tilt can be modified for example through rods or screws, usually located at the
bottom of the antenna, which when moved, applies some corresponding tilt to the antenna.
For example in the above figure, we have a dual antenna (two frequency bands), and of course, 2
rods (1) and (2) that are moved around, and have a small display (3) indicating the corresponding
electrical tilt – one for each band.
And what are the applications?
In the definitions so far, we've already seen that the tilts applications are several, as to minimize
neighboring cells unwanted overlap, e.g. improving the conditions for the handover. Also we can
apply tilt to remove local interference and increase the traffic capacity, and also cases where we
simply want to change the size of certain cells, for example when we insert a new cell.
In A Nutshell: the most important thing is to understand the concept, or effect of each type of
tilt, so that you can apply it as best as possible in each situation.
Final Tips
The tilt subject is far more comprehensive that we (tried to) demonstrate here today, but we
believe it is enough for you to understand the basic concepts.
A final tip is when applying tilts in antennas with more than one band.
This is because in different frequency bands, we have different propagation losses. For this
reason, antennae that allow more than one band has different propagation diagrams, and above
all, different gains and electrical tilt range.
And what's the problem?
Well, suppose as an example an antenna that has the band X, the lower, and a band Y, highest.
Analyzing the characteristics of this specific antenna, you'll see that the ranges of electrical tilt
are different for each band.
For example, for this same dual antenna we can have:
X band: electrical tilt range from 0 to 10 degrees.
Y band: electrical tilt range from 0 to 6 degrees.
The gain of the lower band is always smaller, like to 'adjust' the smaller loss that this band has in
relation to each other. In this way, we can achieve a coverage area roughly equal on both bands –
of course if we use 'equivalent' tilts.
Okay, but in the example above, the maximum is 10 and 6. What would be equivalent tilt?
So the tip is this: always pay attention to the correlation of tilts between antennas with more than
one band being transmitted!
The suggestion is to maintain an auxiliary table, with the correlation of these pre-defined values.
Thus, for the electrical tilt of a given cell:
X Band ET = 0 (no tilt), then Y Band ET = 0 (no tilt). Ok.
X Band ET = 10 (maximum possible tilt), then Y Band ET = 6 (maximum possible tilt).
Ok.
X Band ET = 5. And there? By correlation, Y Band ET = 3!
Obviously, this relationship is not always a 'rule', because it depends on each band specific
diagrams and how each one will reach the areas of interest.
But worth pay attention to not to end up applying the maximum tilt in a band (Y ET = 6), and the
'same' (X ET = 6) in another band – because even though they have the same 'value', actually
they're not 'equivalent'.
After you set this correlation table for your antennas, distribute it to your team – so, when in the
field, when they have to change a tilt of a band they will automatically know the approximate tilt
that should be adjusted in the other(s).
Conclusion
A good tilts choice maintains network interference levels under control, and consequently
provides best overall results.
The application of tilt always results in a loss of coverage, but what one should always bear in
mind is whether the reduced coverage should be there or not!
Knowing well the concept of tilt, and especially understanding the different effects of
mechanical and electrical tilt, you will be able to achieve the best results in your network.
As always, we do that our last ever request: If you liked this tutorial, please share it with your
friends: so you give us reason to continue publishing new articles like this! Thank you!
