AD8017AR-REEL7 Analog Devices Inc, AD8017AR-REEL7 Datasheet - Page 13

AD8017AR-REEL7

Manufacturer Part Number

AD8017AR-REEL7

Description

IC AMP GP DUAL LP LDIST 8SOIC

Manufacturer

Analog Devices Inc

Datasheet

1.AD8017AR-EVAL.pdf (16 pages)

Specifications of AD8017AR-REEL7

Rohs Status

RoHS non-compliant

Amplifier Type

General Purpose

Number Of Circuits

Slew Rate

1600 V/µs

-3db Bandwidth

160MHz

Current - Input Bias

16µA

Voltage - Input Offset

1800µV

Current - Supply

7mA

Current - Output / Channel

270mA

Voltage - Supply, Single/dual (±)

4.4 V ~ 12 V, ±2.2 V ~ 6 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Power Supply Requirement

Single/Dual

Package Type

SOIC N

Pin Count

For Use With

AD8017AR-EVAL - BOARD EVAL FOR AD8017

Output Type

Gain Bandwidth Product

Lead Free Status / Rohs Status

Not Compliant

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The practical maximum value that these resistors can have is

determined by the offset voltage that is created by the input bias

current that flows through them. The maximum input bias

current into the + inputs is 45 µA. This will create an offset

voltage of 45 mV per 1 kΩ of bias resistor. Fortunately, the ac

coupling of the stages provides only unity gain for this dc offset

voltage, which is another advantage of this configuration. Any

dc offset in the output will limit the amount of dynamic signal

swing that will be available between the rails.

The circuit shown uses two 4.7 V Zener diodes that provide a

voltage drop which serves to limit the power dissipation in the

bias circuit. This allows the use of smaller value resistors in the

bias circuit. Thus, for this circuit the current will be (12 V –

(2 × 4.7 V))/2 kΩ = 1.3 mA. Thus, this circuit will dissipate

only 15.6 mW, yet only induce a maximum of 40 mV of offset

at the output. This circuit will also track the midpoint of the

supplies over their specified tolerance range.

The distortion of the circuit was measured with a 50 Ω load.

The frequency used was 500 kHz, which is beyond the maxi-

mum required for the upstream signal. For ADSL over POTS,

a maximum frequency of 135 kHz is required. For ADSL over

ISDN, the maximum frequency is 276 kHz. The amplitude was

20 V p-p (10 V p-p for each amplifier), which is the maximum

crest signal that will be required. The second harmonic was better

than –80 dBc, while the third harmonic was –64 dBc. This

represents a worst case of the absolute maximum signal that will

be required for only a very small statistical basis and at a fre-

quency that is higher than the maximum required. For a statisti-

cal majority of the time, the signal will be at a lower amplitude

and frequency, where the distortion performance will be better.

When the circuit was run while providing the upstream drive signal

in an ADSL system, the supply current to the part was mea-

sured at 25 mA. Thus, the total power to the drive circuit was

300 mW. This power winds up in three places: the drive ampli-

fier, down the line and in the termination and interface circuitry.

The ADSL specification calls for 13 dBm or 20 mW into the line.

The line termination will consume an equal amount of power, as

it is the same resistance value. About a 1 dB loss can be expected

in the losses in the interface circuitry, which translates into about

10 mW of power. Thus, the total power dissipated in the AD8017

when used as a driver in this application is about 250 mW.

VCC

VEE

It is important to consider the total power dissipation of the

AD8017 in order to properly size the heat sinking area for your

application. The dc power dissipation for V

0.17 W. In this purely differential circuit we can use symmetry

to simplify the computation for a dc input signal,

This formula is slightly pessimistic due to the fact that some of

the quiescent supply current commutates during sourcing or

sinking current into the load. For a sine wave source, integration

over a half cycle yields:

The situation is more complicated with a complex modulated

signal. In the case of a DMT signal, taking the equivalent sine wave

power overestimates the power dissipation by > 15%. For example:

at each amplifier output, which yields a P

actual measurement, P

0.38 W of power to be dissipated by the AD8017.

Thermal Considerations

The AD8017 in a “Thermal Coastline” SO-8 package relies on

the device pins to assist in removing heat from the die at a faster

rate than that of conventional packages. The effect is to provide

a lower θ

this, special details should be worked into the copper traces of

the printed circuit board.

There will be a tradeoff, however, between designing a board

that will maximally remove heat, and one that will provide the

desired ac performance. This is the result of the additional para-

sitic capacitance on some of the pins that would be caused by

the addition of extra heat sinking copper traces.

. (V

OUT

= ×

Ω

0.1

0.8

0.7

0.6

0.5

0.4

0.3

0.2

+ V

= 16 dBm = 40 mW

@ 50 Ω = 1.41 V rms or V

for the device. To make the most effective use of

), or 2 × I

= ×

+ ×

OUTPUT VOLTAGE (V

for a DMT signal of 16 dBm requires







× V

V V

. For the AD8017, this number is

+ ×

−

(

= 1.0 V







–

) – V

(Refer to Figure 41)

of 0.436 W. By

)

= 0 is simply,

AD8017

AD8017AR-REEL7 Analog Devices Inc, AD8017AR-REEL7 Datasheet - Page 13

AD8017AR-REEL7

Specifications of AD8017AR-REEL7

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