AD8018(Rev0) 查看數據表（PDF） - Analog Devices

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AD8018
(Rev.:Rev0)

5 V, Rail-to-Rail, High-Output Current, xDSL Line Drive Amplifier

Analog Devices 

AD8018

Table I. Resistor Selection Guide

Gain

–1

+1

+2

+3

+4

+5

RF (⍀)

681

1k

750

511

340

230

RG (⍀)

681

∞

750

256

113

59

POWER-DOWN FEATURES

Two digitally programmable logic pins, PWDN1 and PWDN0,

are available on the TSSOP-14 package to select among three

different modes of operation, full power, standby and shutdown.

The DGND pin is the logic ground reference. The logic thresh-

old voltage is established 1 V above DGND. In a typical 5 V

single-supply application, the DGND pin is connected to analog

ground. If PWDN1, PWDN0, and DGND are left unconnected,

the AD8018 will operate at full power.

Table II. Power-Down Features and Truth Table

PWDN0 PWDN1 State

Supply Output

Current Impedance

High

Low

High

Low

High

High

Low

Low

Full Power

Standby

Standby

Disabled

18 mA

9 mA

9 mA

300 µA

Low

Low

Low

High

POWER SUPPLY AND DECOUPLING

The AD8018 can be powered with a good quality (i.e., low-noise)

supply anywhere in the range from 3.3 V to 8 V. However, in

order to optimize the ADSL upstream drive capability to +13 dBm

and maintain the best Spurious Free Dynamic Range (SFDR),

the AD8018 circuit should be supplied with a well regulated 5 V

supply. The 5 V supplied at the USB port may be poorly regu-

lated. Improving the quality of the 5 V supply will optimize the

performance of the AD8018 in a USB-supplied CPE ADSL

modem. This can be accomplished through the use of a step-up

dc-to-dc converter or switching power supply followed by a low

dropout (LDO) regulator such as the ADP3331 (see Figure 6).

Setting R1 to be 953 kΩ and R2 to be 301 kΩ will result in a

VOUT of 5 V.

Careful attention must be paid to decoupling the power supply

pins at the output of the dc-to-dc converter, the output of the

LDO regulator and the supply pins of the AD8018. High-quality

capacitors with low equivalent series resistance (ESR) such as

multilayer ceramic capacitors (MLCCs) should be used to mini-

mize supply voltage ripple and power dissipation. A large, usually

tantalum, 10 µF to 47 µF capacitor located in proximity to the

AD8018 is required to provide good decoupling for lower fre-

quency signals. In addition, 0.1 µF MLCC decoupling capacitors

should be located as close to each of the power supply pins as is

physically possible, no more than 1/8 inch away. An additional

large (4.7 µF to 10 µF) tantalum capacitor should be placed on the

board near the supply terminals to supply current for fast, large-

signal changes at the AD8018 outputs.

VIN

C1

0.47␮F

ERR

ADP3331

OUT

IN

FB

SD

GND

ON

OFF

R3

330k⍀

R1

953k⍀

R2

301k⍀

EOUT

VOUT

C2

0.47␮F

Figure 6. ADP3331 LDO

METHOD FOR GENERATING A MIDSUPPLY VOLTAGE

To operate an amplifier on a single voltage supply, a voltage

midway between the supply and ground must be generated to

properly bias the inputs and the outputs.

A voltage divider can be created with two equal value resistors

(Figure 7). There is a trade-off between the power consumed by

the divider and the voltage drop across these resistors due to the

positive input bias currents. Selecting 2.5 kΩ for R1 and R2 will

create a voltage divider that draws only 1 mA from a 5 V supply.

The voltage generated with this topology can vary due to the

temperature coefficient (TC) of resistance. Resistors that are

closely matched and have a low TC will minimize variations in

the voltage reference due to temperature. One should also be

sure to use a decoupling capacitor (0.1 µF) at the node where

VREF is generated.

5V

R1

2.5k⍀

R2

2.5k⍀

VREF

0.1␮F

Figure 7. Midsupply Reference

DIFFERENTIAL TESTING

The test circuit shown in TPC 13 is used for measuring the dif-

ferential distortion of the AD8018. A single-ended test signal is

applied to the inverting input of the AD8138 differential driver

with the noninverting input grounded. Applying the differential

output of the AD8138 through 100 Ω resistors serves to isolate

the inputs of the AD8018 differential driver and provide a well-

balanced low-distortion input signal. The differential load (RL)

of the AD8018 can be set to the equivalent of the line imped-

ance reflected through a transformer. The AD9632 converts

the differential output voltage back to a single-ended signal.

The differential-to- single-ended converter using the AD9632

has an attenuation of –26 dB and is wired with precision resis-

tors to optimize the balance of differential input signal. The

resulting smaller output signal can be easily measured using a

50 Ω spectrum analyzer.

REV. 0

–9–

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