User's Manual
Table Of Contents
- Part A – Preface
- Warranty
- Important Notice
- FCC Compliance Notices
- Australian Compliance Notices
- Other Related Documentation and Products
- Revision History
- Part B – O Series Overview
- Definition of O Series Data Radio
- O Series Product Range
- O Series – Features and Benefits
- Standard Accessories
- Part C – Applications
- Application Detail
- Part D – Module Pinouts
- Part E – System Planning and Design
- Understanding RF Path Requirements
- Examples of Predictive Path Modelling
- Selecting Antennas
- Part F – Suggested Interface Circuits
Page 12
© Copyright 2008 Trio DataCom Pty. Ltd.
O Series Data Radio – User Manual
Antenna Placement
When mounting the antenna, it is necessary to consider the
following criteria:
The mounting structure will need to be solid enough to withstand
additional loading on the antenna mount due to extreme wind, ice
or snow (and in some cases, large birds).
For omni directional antennas, it is necessary to consider the
effect of the mounting structure (tower mast or building) on the
radiation pattern. Close in structures, particularly steel structures,
can alter the radiation pattern of the antenna. Where possible,
omni antennas should always be mounted on the top of the mast
or pole to minimise this effect. If this is not possible, mount the
antenna on a horizontal outrigger to get it at least 1-2m away from
the structure. When mounting on buildings, a small mast or pole
(2-4m) can signifi cantly improve the radiation pattern by providing
clearance from the building structure.
For directional antennas, it is generally only necessary to consider
the structure in relation to the forward radiation pattern of the
antenna, unless the structure is metallic, and of a solid nature.
In this case it is also prudent to position the antenna as far away
from the structure as is practical. With directional antennas, it is
also necessary to ensure that the antenna cannot move in such
a way that the directional beamwidth will be affected. For long
yagi antennas, it is often necessary to install a fi breglass strut to
stablilise the antenna under windy conditions.
Alignment of Directional Antennas
This is generally performed by altering the alignment of the
antenna whilst measuring the received signal strength. If the
signal is weak, it may be necessary to pre-align the antenna using
a compass, GPS, visual or map guidance in order to “fi nd” the
wanted signal. Yagi antennas have a number of lower gain “lobes”
centred around the primary lobe. When aligning for best signal
strength, it is important to scan the antenna through at least 90
degrees, to ensure that the centre (strongest) lobe is identifi ed.
When aligning a directional antenna, avoid placing your hands or
body in the vicinity of the radiating element or the forward beam
pattern, as this will affect the performance of the antenna.
Common Cable Types Loss per 30.5m Loss per 30.5m
@ 915MHz @ 2.4GHz
RG213/U 7.4dB 23.6dB
FSJ1-50 (¼” superfl ex) 5.6dB 9.9dB
LDF4-50 (1/2” heliax) 2.2dB 2.3dB
LDF5-50 (7/8” heliax) 1.2dB 3.7dB
RF Feeders and Protection
The antenna is connected to the radio modem by way of an
RF feeder. In choosing the feeder type, one must compromise
between the loss caused by the feeder, and the cost, fl exibility, and
bulk of lower loss feeders. To do this, it is often prudent to perform
path analysis fi rst, in order to determine how much “spare” signal
can be allowed to be lost in the feeder. The feeder is also a critical
part of the lightning protection system.
All elevated antennas may be exposed to induced or direct
lightning strikes, and correct grounding of the feeder and mast are
an essential part of this process. Gas discharge lightning arresters
should also be fi tted to all sites.
Note: All ETSI installations require the use of a lightning surge
arrestor in order to meet EN6095.
Common Cable Types Loss per 30.5m Loss per 30.5m
RG213/U 7.4dB 23.6dB
FSJ1-50 (¼” superfl ex) 5.6dB 9.9dB
LDF4-50 (1/2” heliax) 2.2dB 2.3dB
LDF5-50 (7/8” heliax) 1.2dB 3.7dB
Common Cable Types Loss per 30.5m Loss per 30.5m
@ 915MHz @ 2.4GHz
RG213/U 7.4dB 23.6dB
FSJ1-50 (¼” superfl ex) 5.6dB 9.9dB
LDF4-50 (1/2” heliax) 2.2dB 2.3dB
LDF5-50 (7/8” heliax) 1.2dB 3.7dB
TX Power for Maximum EIRP (FCC)
FCC Regulations allow up to 36 dBm effective isotropic radiated
power (EIRP). To calculate the maximum transmitter power you
need to know the gain of the antenna being used (see the FCC
Approved Antenna List Appendix) and the cabling loss. The
maximum transmitter power can then be calculated using the
following formula:
Maximum transmitter power (dBm) = 36dBm + cable loss (dB)
– antenna gain (dBd) - 2.15.
As an example, if we choose the BMY890K yagi from the FCC
Approved Antenna List which has a gain of 10dBd and we know
the cable loss is 3dB then the maximum output power is:
Maximum output power (dBm) = 36 + 3 -10 - 2.15 = 26.85 dBm.
Rounded down to 26dBm. Therefore the radio TX power should be
set to 26dBm.
Other countries may have different EIRP limits, but the same
method for calculation applies.
FCC Point to Point : More EIRP may be allowed for fi xed point to
point links. With the transmitter set to 27dBm, an antenna gain
(subtracting cable loss) of up to 15 dBi is allowed. For antenna
gains of more than 15 dBi in a fi xed point to point link, the power
must be backed off from 27dBm by 1dB for every 3dB the antenna
gain exceeds 15dBi.
ETSI Maximum EIRP for the 2.4GHz band is +20dBm.