TQ9147B Ver la hoja de datos (PDF) - TriQuint Semiconductor
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TQ9147B Datasheet PDF : 10 Pages
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TQ9147B
Data Sheet
Drain current for the second stage is injected through L1 (47
nH), which acts as an RF choke on the high power DC feed line.
As stated above, C1 is the bypass cap for the high impedance
side of L1.
Power down Function
To fully turn off the PA when not transmitting, a PMOS FET
(PFET) switch can be used to control the drain bias to the PA.
There are several acceptable models available on the market,
such as the IRF7604 from International Rectifier, or any device
with low RDSon. An added benefit of incorporating a switch of
this type is that it protects the PA from inadvertently powering up
the device incorrectly. Since depletion-mode FETs are used in
the PA, care must be taken to insure that the gate bias is fully
stabilized before drain bias is applied. If not, the full value of IDss
will flow, which could damage or destroy the IC. A feature
included in the Maxim charge pump allows for a separate
control output to run the PFET. This control line holds the PFET
off until the gate bias voltage has stabilized.
RF Power Control
There are three methods of controlling the output power from
the TQ9147. All three methods can provide a minimum 25 dB of
control range for the device, which exceeds the requirements of
IS-19.
The first method is to vary the gate bias voltages. Though this
approach has the advantage of increased efficiency at lower
output power levels, it is hampered by two problems. First, both
gate voltages must be varied. Since each stage typically
requires a different bias point, the control circuit must monitor
both bias points, thereby complicating the design.
The second drawback is that most charge pumps, including
those recommended above, require large capacitors on the
output for filtering and stability. Such large cap values may not
allow full compliance with the required 20 mS transition spec
between any two power levels.
The second method is to vary the input power level. Though
this can be done with a simple attenuator between the driver
amp and the PA, the response is very non-linear, as the PA
must first come out of saturation before the output power can
change. Once out of saturation, the first stage is class A biased,
which means that the drain current is constant regardless of
power settings. The addition of an attenuator also adds to the
expense of the parts list and to the board size equation, and
increases the insertion loss the driver amp must overcome.
The third, and preferred, method is to vary the drain supply
voltage to the first stage. By forcing the first stage bias lower,
the first stage is always heavily saturated, thus saving battery
power. Since the second stage is biased class AB, drain current
to that stage lowers as the drive level decreases. This method
optimizes battery savings over the other approaches. The
simplest implementation of this technique would be to
incorporate a second PFET to control the first stage drain. This
circuit can be realized buy utilizing a dual PFET such as the
International Rectifier IRF7314, which has two low RDSon FETs in
a single SO-8 package. By cascoding the two FETs, one
implements a master on/off function while the second controls
only the first stage drain bias. This technique also fits very well
with the active gate biasing circuit that was recommended
previously.
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