AD8004AR Datasheet, PDF(12/17 Page) Analog Devices – Quad 3000 V/s, 35 mW Current Feedback Amplifier

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AD8004AR Datasheet, PDF (12/17 Pages) Analog Devices – Quad 3000 V/s, 35 mW Current Feedback Amplifier

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AD8004

G = +2, RF = 1.10kâ

CL = 10pF

G = â2, RF = 698â

CL = 0

â2

â4

â2

â4

VIN = 50mV

â6 Ø5VS

RL = 100â

â8

â6

CL = 10pF

â8

â10

CL = 0

â12

â10

â14

â12

â14

100

500

FREQUENCY â MHz

Figure 10. Frequency Response vs. Capacitive Loading,

RL = 100 â¦ Output

G = +2

â2 RL = 1kâ

Ø5VS

â4 VIN = 50mV rms

RF = 1.2kâ

â6

CL = 10pF

CL = 0

â8

â10

â12

â14

100

500

FREQUENCY â MHz

Figure 11. Flatness with 10 pF Capacitive Load

DRIVING A SINGLE-SUPPLY A/D CONVERTER

New CMOS A/D converters are placing greater demands on the

amplifiers that drive them. Higher resolutions, faster conversion

rates, and input switching irregularities require superior settling

characteristics. In addition, these devices run off a single +5 V

supply and consume little power, so good single-supply operation

with low power consumption is very important. The AD8004 is

well positioned for driving this new class of A/D converters.

Figure 12 shows a circuit that uses an AD8004 to drive an

AD876, a single supply, 10-bit, 20 MSPS A/D converter that

requires only 140 mW. Using the AD8004 for level shifting and

driving, the A/D exhibits no degradation in performance com-

pared to when it is driven from a signal generator.

The analog input of the AD876 spans 2 V centered at about

2.6 V. The resistor network and bias voltages provide the level

shifting and gain required to convert the 0 V to 1 V input signal

to a 3.6 V to 1.6 V range that the AD876 wants to see.

Biasing the noninverting input of the AD8004 at 1.6 V dc forces

the inverting input to be at 1.6 V dc for linear operation of the

amplifier. When the input is at 0 V, there is 3.2 mA flowing out

of the summing junction via R1 (1.6 V/499 â¦). R3 has a current

of 1.2 mA flowing into the summing junction (3.6 V â 1.6 V)/

1.65 kâ¦. The difference of these two currents (2 mA) must flow

through R2. This current flows toward the summing junction

and requires that the output be 2 V higher than the summing

junction or at 3.6 V.

When the input is at 1 V, there is 1.2 mA flowing into the sum-

ming junction through R3 and 1.2 mA flowing out through R1.

These currents balance and leave no current to flow through

R2. Thus the output is at the same potential as the inverting

input or 1.6 V.

The input of the AD876 has a series MOSFET switch that turns

on and off at the sampling rate. This MOSFET is connected to

a hold capacitor internal to the device. The on impedance of the

MOSFET is about 50 â¦, while the hold capacitor is about 5 pF.

In a worst case condition, the input voltage to the AD876 will

change by a full-scale value (2 V) in one sampling cycle. When

the input MOSFET turns on, the output of the op amp will be

connected to the charged hold capacitor through the series

resistance of the MOSFET. Without any other series resistance,

the instantaneous current that flows would be 40 mA. This

would cause settling problems for the op amp.

The series 100 â¦ resistor limits the current that flows instanta-

neously after the MOSFET turns on to about 13 mA. This

resistor cannot be made too large or the high frequency perfor-

mance will be affected.

The sampling MOSFET of the AD876 is closed for only half of

each cycle or for 25 ns. Approximately seven time constants are

required for settling to 10 bits. The series 100 â¦ resistor along

with the 50 â¦ on resistance and the hold capacitor, create a

750 ps time constant. These values leave a comfortable margin

for settling. Obtaining the same results with the op amp A/D

combination as compared to driving with a signal generator

indicates that the op amp is settling fast enough.

Overall the AD8004 provides adequate buffering for the AD876

A/D converter without introducing distortion greater than that

of the A/D converter by itself.

+5V

3.6V

1.65kâ

1kâ

0.1â®F

10â®F

0.1â®F

VIN

499kâ

+3.6V

REFT

50â

1/4

AD8004

100â

AD876

3.6V

0.1â®F

1.6V

REFB

1.6V

+1.6V

Figure 12. AD8004 Driving the AD876

LAYOUT CONSIDERATIONS

The specified high speed performance of the AD8004 requires

careful attention to board layout and component selection.

Table I shows the recommended component values for the

AD8004 and Figures 14â16 show the layout for the AD8004

evaluation boards (14-lead DIP and SOIC). Proper RF design

techniques and low parasitic component selection are mandatory.

REV. C

â11â

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