8.3.4 Steptrack Parameters
The behavior of the satellite step track is adjustable with a couple
of parameters. This permits to tune the step track performance for
special preconditions arising from the antenna and also the satellite.
The first parameters listed below are setup parameters, they are set
once for an ACU installation to adapt the ACU to the antenna and the
beacon receiver.
- AZAntennadiameter
ELAntennadiameter --- The diameter values are used by
the ACU software to evaluate the antenna's beamwidth. There are separate
values for both axes to handle offset antennas as well.
- BeaconRXtype --- With this parameter you specify
which type of beacon receiver. For a sat-nms LBRX beacon receiver set it
to 'SATNMS' and set the receiver's IP address accordingly. To make ACU
and beacon receiver work together you should take care of the following:
- ACU and beacon receiver must be connected to the same Ethernet
segment.
- Both devices must have assigned IP addresses in the same
subnet.
- The LBRX beacon receiver must be configured for the correct LO
frequency. The displayed receive frequency must be the true RX frequency
rather than the L-band frequency.
- At the sat-nms LBRX the ACU's IP address must be set as the 'UDP
destination address'.
The setting 'VOLTAGE' is used with any other type of beacon receiver
or with a sat-nms LBRX beacon receiver which has no TCP/IP connection to
the ACU.When operating in SATNMS mode, the ACU will automatically
determine the beacon frequency from the sat-nms beacon receiver. Also
the beacon receiver's background activities like frequency tracking and
noise reference measurements get synchronized to the step track sequence
in this mode. These features are not available in the VOLTAGE operating
mode.
- BeaconRXIPaddress --- You need to enter the beacon
receiver's IP address in 'dotted quad' notation here if the receiver
tape is set to 'SATNMS'.
- BeaconRXvoltagescale
BeaconRX0Vlevel --- These parameters define the slope
and offset of the beacon level voltage. The values must be set to match
settings of the beacon receiver. With the
sat-nms LBRX beacon receiver you can set these
parameters there as well, chapter '8.3.2 ACU And Beacon
Receiver' explains how to find the best settings for this.
The parameters in the table below are to be set individually for each
satellite. They are set at the 'Tracking' page and stored with each
target memory.
- BeaconRXfrequency --- This parameter is only of
interest if a third party beacon receiver is used. The beacon frequency
(you must enter the frequency received by the antenna [MHz], not the IF
frequency seen by the receiver.) is used by the ACU to calculate the
antenna's beamwidth and an approximated beam pattern. With the
sat-nms LBRX beacon receiver, the ACU
automatically reads the frequency from the receiver.
- Trackingcycletime --- The cycle time specifies how
often the ACU shall perform a step track cycle. The value is to be
entered in seconds. In fact, the parameter does not specify a cycle time
but the sleep time between two tracking cycles. This means, the true
cycle time is the time the ACU needs to perform one step track cycle
plus the time entered here. 300 seconds (5 minutes) is a good starting
value for this parameter. Inclined orbit satellites probably will
require a shorter cycle time, very stable satellites can be perfectly
tracked with one step track cycle every 15 minutes (900 seconds).
- Trackingstepsize --- The tracking step size is a
very important parameter for the performance of the tracking. It defines
the size of every depointing step, the ACU makes in order to find out
where the optimal antenna pointing is. Setting too high values will
cause significant signal degradations during the step track cycle
because the antenna moves a too large amount away from the satellite.
Setting the value too small will let the beacon level jitter mask the
level differences caused by the test steps, the antenna will not track
the satellite properly.The step size is specified as a percentage of the
antenna's half 3dB beamwidth. The ACU calculates the beamwidth from the
antenna diameter and the beacon frequency. Expressing the step size in
this relative way keeps the value in the same range, regardless of the
type of antenna. The recommended value for this parameter is 15-20%. You
may want to start with 20% and try to reduce down to 15% if the signal
degradation during tracking becomes too high.The tracking step size is a
common parameter for both axes. If both axes behave differently, you can
tweak the antenna diameter settings in the setup. Specifying a larger
diameter makes the ACU using a smaller step size for this axis.If the
tracking step seems to be completely out of range, you should check if
the beacon frequency is set properly. The frequency must be the true
receive frequency at the antenna, entered in MHz, not an L-band
frequency or other IF.
- Trackingmode --- The tracking mode parameter
switches the steptrack on or off. With the operation modes 'STEP' and
'ADAPTIVE' the ACU performs steptrack.
- Levelaveraging --- When measuring the beacon level,
the ACU takes a number of samples and averages them. The standard value
of 5 samples normally should not be changed. Larger values will slow
down the ACU execution cycle.
- Levelthreshold --- If the beacon level drops below
this value, the ACU raises a fault signal. Steptrack is inhibited while
the beacon level is too low, the antenna position freezes.
- Recoverydelay --- After the the ACU has done the
tracking steps for the elevation axis, it waits some time before it
starts tracking the azimuth axis. This is to let the beacon level settle
after the final position has been found. A typical value for this
parameter is 4000 msec.
- Measurementdelay --- During a steptrack cycle, the
ACU positions the antenna to a certain offset and then measures the
level. Between the moment when the antenna reached commanded position
and the beacon level measurement the ACU waits some time to let the
beacon level settle. The optimal delay value depends on the beacon
receiver's averaging / post detector filter setting and is a quite
critical for the steptrack performance.If the delay is too short, the
beacon voltage does not reach its final value, the steptrack does not
properly recognize if the signal gor better or worse after a test step.
If the delay is too long, the impact of fluctuation to the measures
level grows and may cover the small level difference caused by the test
step. With the sat-nms LBRX beacon receiver,
best results are achieved if the receiver is set to 0.5 Hz post detector
filter bandwidth and a measurement delay of 1500 msec.
- Smoothinginterval --- This parameter controls the
smoothing function. Setting it to zero disables smoothing. A detailed
description of this function you find at chapter '8.3.3
Smoothing'