ADL5320-EVALZ(Rev0) Ver la hoja de datos (PDF) - Analog Devices
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ADL5320-EVALZ Datasheet PDF : 16 Pages
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ADL5320
MATCHING PROCEDURE
The ADL5320 is designed to achieve excellent gain and IP3
performance. To achieve this, both input and output matching
networks must present specific impedance to the device. The
matching components listed in Table 6 were chosen to provide
−10 dB input return loss while maximizing OIP3. The load-pull
plots (Figure 28, Figure 29, and Figure 30) show the load
impedance points on the Smith chart where optimum OIP3,
gain, and output power can be achieved. These load impedance
values (that is, the impedance that the device sees when looking
into the output matching network) are listed in Table 7 and
Table 8 for maximum gain and maximum OIP3, respectively.
The contours show how each parameter degrades as it is moved
away from the optimum point.
From the data shown in Table 7 and Table 8 it becomes clear that
maximum gain and maximum OIP3 do not occur at the same
impedance. This can also be seen on the load-pull contours in
Figure 28 through Figure 30. Thus, output matching generally
involves compromising between gain and OIP3. In addition,
the load-pull plots demonstrate that the quality of the output
impedance match must be compromised to optimize gain
and/or OIP3. In most applications where line lengths are short
and where the next device in the signal chain presents a low
input return loss, compromising on the output match is
acceptable.
To adjust the output match for operation at a different
frequency or if a different trade-off between OIP3, gain,
and output impedance is desired, the following procedure
is recommended.
For example, to optimize the ADL5320 for optimum OIP3 and
gain at 700 MHz use the following steps:
1. Install the recommended tuning components for a 800 MHz
to 960 MHz tuning band, but do not install C3 and C7.
2. Connect the evaluation board to a vector network analyzer
so that input and output return loss can be viewed simulta-
neously.
3. Starting with the recommended values and positions for
C3 and C7, adjust the positions of these capacitors along
the transmission line until the return loss and gain are
acceptable. Push-down capacitors that are mounted on
small sticks can be used in this case as an alternative to
soldering. If moving the component positions does not
yield satisfactory results, then the values of C3 and C7
should be increased or decreased (most likely increased
in this case as the user is tuning for a lower frequency).
Repeat the process.
4. Once the desired gain and return loss are realized, OIP3
should be measured. Most likely, it will be necessary to
go back and forth between return loss/gain and OIP3
measurements (probably compromising most on output
return loss) until an acceptable compromise is achieved.
Rev. 0 | Page 12 of 16
Figure 28. Load-Pull Contours, 880 MHz
Figure 29. Load-Pull Contours, 2140 MHz
Figure 30. Load-Pull Contours, 2600 MHz
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