EVAL-ADF7021-VDB2Z Analog Devices Inc, EVAL-ADF7021-VDB2Z Datasheet - Page 37

EVAL-ADF7021-VDB2Z

Manufacturer Part Number

EVAL-ADF7021-VDB2Z

Description

868 - 870MHz - EVALUATION BOARD

Manufacturer

Analog Devices Inc

Type

Transceiverr

Datasheet

1.EVAL-ADF7021-VDB2Z.pdf (60 pages)

Specifications of EVAL-ADF7021-VDB2Z

Frequency

868MHz ~ 870MHz

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With/related Products

ADF7021

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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When to Use Fine Calibration

In cases where the receive signal bandwidth is very close to the

bandwidth of the IF filter, it is recommended that a fine filter

calibration be performed every time that the unit powers up in

receive mode.

A fine calibration should be performed if

where:

OBW is the 99% occupied bandwidth of the transmit signal.

Coarse Calibration Variation is 2.5 kHz.

IF_FILTER_BW is set by Register 4, Bits[DB31:DB30].

The FILTER_CAL_COMPLETE signal from MUXOUT (set by

calibration duration or to signal the end of calibration. A coarse

filter calibration is automatically performed prior to a fine filter

calibration.

When to Use Single Fine Calibration

In applications where the receiver powers up numerous times

in a short period, it is necessary to perform fine calibration only

once, on the initial power-up in receive mode.

After the initial coarse calibration and fine calibration, the result

of the fine calibration can be read back through the serial inter-

face using the FILTER_CAL_READBACK result (see the Filter

Bandwidth Calibration Readback section). On subsequent

power-ups in receive mode, the filter is manually adjusted using

the previous fine filter calibration result. This manual adjustment

is performed using the IF_FILTER_ADJUST bits (Register 5,

Bits[DB19:DB14]).

This method should only be used if the successive power-ups in

receive mode are over a short duration, during which time there

is little variation in temperature (<15°C).

IF Filter Variation with Temperature

When calibrated, the filter center frequency can vary with changes

in temperature. If the ADF7021-V is used in an application where

it remains in receive mode for a considerable length of time, the

user must consider this variation of filter center frequency with

temperature. This variation is typically 1 kHz per 20°C, which

means that if a coarse filter calibration and fine filter calibration

are performed at 25°C, the initial maximum error is ±0.5 kHz,

and the maximum possible change in the filter center frequency

over temperature (−40°C to +85°C) is ±3.25 kHz. This gives a

total error of ±3.75 kHz.

If the receive signal occupied bandwidth is considerably

narrower than the IF filter bandwidth, the variation of filter

center frequency over the operating temperature range may

not be an issue. However, if the IF filter bandwidth is not wide

enough to tolerate the variation with temperature, a periodic

filter calibration can be performed or, alternatively, the on-chip

temperature sensor can be used to determine when a filter cali-

bration is necessary by monitoring for changes in temperature.

OBW + Coarse Calibration Variation > IF_FILTER_BW

Rev. 0 | Page 37 of 60

LNA/PA MATCHING

The ADF7021-V exhibits optimum performance in terms of

sensitivity, transmit power, and current consumption only if its

RF input and output ports are properly matched to the antenna

impedance. For cost-sensitive applications, the ADF7021-V is

equipped with an internal Tx/Rx switch that facilitates the use

of a simple, combined passive LNA/PA matching network.

Alternatively, an external Tx/Rx switch such as the

be used, which yields a slightly improved receiver sensitivity

and lower transmitter power consumption.

Internal Tx/Rx Switch

Figure 49 shows the ADF7021-V in a configuration where

the internal Tx/Rx switch is used with a combined LNA/PA

matching network. This is the configuration used on the

EVAL-ADF7021-VDBxZ evaluation board. For most applica-

tions, the slight performance degradation of 1 dB to 2 dB

caused by the internal Tx/Rx switch is acceptable, allowing

the user to take advantage of the cost-saving potential of this

solution. The design of the combined matching network must

compensate for the reactance presented by the networks in the

Tx and the Rx paths, taking the state of the Tx/Rx switch into

consideration.

The procedure typically requires several iterations until an accept-

able compromise is reached. The successful implementation of

a combined LNA/PA matching network for the ADF7021-V is

critically dependent on the availability of an accurate electrical

model for the PCB. In this context, the use of a suitable CAD

package is strongly recommended. To avoid this effort, a small

form-factor reference design for the ADF7021-V is provided,

including matching and harmonic filter components. The design is

on a 4-layer PCB. Gerber files are available at www.analog.com.

ANTENNA

BPF OR LPF

OPTIONAL

Figure 49. ADF7021-V with Internal Tx/Rx Switch

BAT

OPT

_RFIN

_PA

RFOUT

RFIN

ADF7021-V

ADG919

LNA

can

EVAL-ADF7021-VDB2Z Analog Devices Inc, EVAL-ADF7021-VDB2Z Datasheet - Page 37

EVAL-ADF7021-VDB2Z

Specifications of EVAL-ADF7021-VDB2Z

Related parts for EVAL-ADF7021-VDB2Z