MAX2010ETI+ Maxim Integrated Products, MAX2010ETI+ Datasheet - Page 15

MAX2010ETI+

Manufacturer Part Number

MAX2010ETI+

Description

RF Wireless Misc IC RF PREDISTORT ADJ justable RF Predisto

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX2010ETI.pdf (19 pages)

Specifications of MAX2010ETI+

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The gain expansion breakpoint is usually controlled by

a DAC connected through the GBP pin. The GBP input

voltage range of 0.5V to 5V corresponds to a break-

point input power range of -2.5dBm to 23dBm. To

achieve the optimal performance, the gain expansion

breakpoint of the MAX2010 must be set to equal the

gain compression point of the PA. The GBP control has

a minimal effect on the small-signal gain when operat-

ed from 0.5V to 5V.

In addition to properly setting the breakpoint, the gain

expansion slope of the MAX2010 must also be adjusted

to compensate for the PA’s gain compression. The

slope should be set using the following equation:

where:

MAX2010_SLOPE = MAX2010 gain section’s slope in

dB/dB.

PA_SLOPE = PA’s gain slope in dB/dB, a negative

number for compressive behavior.

To modify the gain expansion slope, two adjustments

must be made to the biases applied on pins GCS and

GFS. Both GCS and GFS have an input voltage range of

0V to V

0.1dB/dB to 0.53dB/dB. The slope is set to maximum

when V

minimum when V

Unlike the GBP pin, modifying the gain expansion slope

bias on the GCS pin causes a change in the part’s inser-

tion loss and noise figure. For example, a smaller slope

caused by GCS results in a better insertion loss and

lower noise figure. The GFS does not affect the insertion

loss. It can provide up to -30% or +30% total slope varia-

tion around the nominal slope set by GCS.

Large amounts of GCS bias adjustment can also lead to

an undesired (or residual) phase expansion/compres-

sion behavior. There exists an optimal bias voltage that

minimizes this parasitic behavior (typically GCS = 1.0V).

Control voltages higher than the optimal result in para-

sitic phase expansion, lower control voltages result in

phase compression. GFS does not contribute to the

phase behavior and is preferred for slope control.

GCS

MAX

, corresponding to a slope of approximately

= 0V and V

2010

GCS

______________________________________________________________________________________

SLOPE

= +5V and V

GFS

Gain Expansion Breakpoint

= +5V, and the slope is at its

−

Gain Expansion Slope

PA SLOPE

GFS

= 0V.

500MHz to 1100MHz Adjustable

The following section describes the tuning methodology

best implemented with a class A amplifier. Other classes

of operation may require significantly different settings.

The best approach to improve the ACPR of a PA is to

first optimize the AM-PM response of the phase sec-

tion. For most high-frequency LDMOS amplifiers,

improving the AM-PM response provides the bulk of the

ACPR improvement. Figure 4 shows a typical configu-

ration of the phase tuning circuit. A power sweep on a

network analyzer allows quick real-time tuning of the

AM-PM response. First, tune PBIN to achieve the phase

expansion starting point (breakpoint) at the same point

where the PA’s phase compression begins. Next, use

control pins PF_S1, PDCS1, and PDCS2 to obtain the

optimal AM-PM response. The typical values for these

pins are shown in Figure 4.

To further improve the ACPR, connect the phase out-

put to the gain input through a preamplifier. The pre-

amplifier is used to compensate for the high insertion

loss of the gain section. Figure 5 shows a typical appli-

cation circuit of the MAX2010 with the phase section

cascaded to the gain section for further ACPR opti-

mization. Similar to tuning the phase section, first tune

the gain expansion breakpoint through the GBP pin

and adjust for the desired gain expansion with pins

GCS and GFS. To minimize the effect of GCS on the

parasitic phase response, minimize the control voltage

to around 1V. Some retuning of the AM-PM response

may be necessary.

A properly designed PC board is an essential part of any

high-frequency circuit. In order to minimize external com-

ponents, the PC board can be designed to incorporate

small values of inductance and capacitance to optimize

the input and output VSWR (refer to the MAX2009/

MAX2010 EV Kit). The phase section’s PFS1 and PFS2

pins are sensitive to external parasitics. Minimize trace

lengths and keep varactor diodes close to the pins.

Remove the ground plane underneath the traces can fur-

ther help reduce the parasitic capacitance. For best per-

formance, route the ground pin traces directly to the

grounded EP underneath the package. Solder the EP on

the bottom of the device package evenly to the board

ground plane to provide a heat transfer path along with

signal grounding.

Gain and Phase Expansion Optimization

Applications Information

RF Predistorter

Layout Considerations

MAX2010ETI+ Maxim Integrated Products, MAX2010ETI+ Datasheet - Page 15

MAX2010ETI+

Specifications of MAX2010ETI+

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