u-blox NEO-5 Series, Hardware Integration Manual

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NEO-5 - Hardware Integration Manual Preliminary Product Testing
GPS.G5-MS5-08003-A2 u-blox proprietary Page 39
GPS/GALILEO applications with position resolution in the millimeter range it is important that signals from
satellites at all elevations virtually meet at exactly the same point inside the antenna. For these types of
applications receivers with multiple antenna inputs are often required.
At the low end of the spectrum of possible antenna solutions - if the user is willing to accept significant signal
losses - a simple linear polarized whip or strip antenna will work. Compared to a circular polarized antenna, a
minimum of 3 dB of signal to noise ratio will be lost.
B.2 Active and Passive Antennas
Passive antennas contain only the radiating element, e.g. the ceramic patch or the helix structure. Sometimes
they also contain a passive matching network to match the electrical connection to 50 Ohms impedance.
Active antennas have an integrated low-noise amplifier. This is beneficial in two respects. Firstly, the losses of the
cable no longer affect the overall noise figure of the GPS/GALILEO receiver system. Secondly, the receiver noise
figure can be much higher without sacrificing performance. Therefore, some receivers will only work with active
antennas. Active antennas require a power supply that contributes to total GPS/GALILEO system power
consumption, typically in the region of 5 to 20mA. Usually, the supply voltage is fed to the antenna through the
coaxial RF cable. Inside the antenna, the DC component on the inner conductor will be separated from the RF
signal and routed to the supply pin of the LNA.
The use of an active antenna is always advisable if the RF-cable length between receiver and antenna exceeds
approximately 10 cm. Care should be taken that the gain of the LNA inside the antenna does not lead to an
overload condition at the receiver. For receivers that also work with passive antennas, an antenna LNA gain of
15 dB is usually sufficient, even for cable lengths up to 5 m. There’s no need for the antenna LNA gain to exceed
26 dB for use with u-blox receivers. With shorter cables and a gain above 25 dB, an overload condition might
occur on some receivers.
When comparing gain measures of active and passive antennas one has to keep in mind that the gain of an
active antenna is composed of two components, the antenna gain of the passive radiator, given in dBic, and the
LNA power gain given in dB. A low antenna gain cannot be compensated by high LNA gain. If a manufacturer
provides one total gain figure, this is not sufficient to judge the quality of the antenna. One would need
information on antenna gain (in dBic), amplifier gain, and amplifier noise figure.
B.3 Patch Antennas
Patch antennas are ideal for an application where the antenna sits on a flat surface, e.g. the roof of a car. Patch
antennas can demonstrate a very high gain, especially if they are mounted on top of a large ground plane.
Ceramic patch antennas are very popular because of their small size, typically measuring 25 x 25 mm
2
down to
12x12mm
2
. Very cheap construction techniques might use ordinary circuit board material like FR-4 or even air as
a dielectric, but this will result in a much larger size, typically in the order of 10 x 10 cm
2
. Figure 25 shows a
typical example of the radiation pattern of a 16 x 16 mm
2
ceramic patch antenna. This measurement only shows
the upper sphere of the radiation pattern. Depending on ground plane size there will also be a prominent back
lobe present.