AD8057AR-REEL Analog Devices Inc, AD8057AR-REEL Datasheet - Page 14

AD8057AR-REEL

Manufacturer Part Number

AD8057AR-REEL

Description

IC OPAMP VF LN LP LDIST 8SOIC

Manufacturer

Analog Devices Inc

Datasheet

1.AD8058ARZ.pdf (16 pages)

Specifications of AD8057AR-REEL

Rohs Status

RoHS non-compliant

Amplifier Type

Voltage Feedback

Number Of Circuits

Slew Rate

1150 V/µs

-3db Bandwidth

325MHz

Current - Input Bias

500nA

Voltage - Input Offset

1000µV

Current - Supply

6mA

Voltage - Supply, Single/dual (±)

3 V ~ 12 V, ±1.5 V ~ 6 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Output Type

Current - Output / Channel

Gain Bandwidth Product

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AD8057/AD8058

Figure 47 shows a frequency sweep of this filter. The response is

down 3 dB at 5.7 MHz; therefore, it passes the video band with

little attenuation. The rejection at 27 MHz is 42 dB, which

provides more than a factor of 100 in suppression of the clock

components at this frequency.

DIFFERENTIAL ANALOG-TO-DIGITAL DRIVER

As system supply voltages are dropping, many ADCs provide

differential analog inputs to increase the dynamic range of the

input signal while still operating on a low supply voltage.

Differential driving can also reduce second and other even-

order distortion products.

Analog Devices, Inc., offers an assortment of 12- and 14-bit

high speed converters that have differential inputs and can be

run from a single 5 V supply. These include the AD9220, AD9221,

AD9223, AD9224, and

AD9241, and

operate over a range of common-mode voltages at their analog

inputs, they work best when the common-mode voltage at the

input is at the midsupply or 2.5 V.

Op amp architectures that require upwards of 2 V of headroom

at the output have significant problems when trying to drive

such ADCs while operating with a 5 V positive supply. The low

headroom output design of the AD8057 and AD8058 make

them ideal for driving these types of ADCs.

The AD8058 can be used to make a dc-coupled, single-ended-

to-differential driver for one of these ADCs. Figure 48 is a

schematic of such a circuit for driving an AD9225, 12-bit, 25

MSPS ADC.

–10

–20

–30

–40

–50

–60

–70

–80

–90

100k

AD9243

Figure 47. Video Filter Response

at 14 bits. Although these devices can

AD9225

FREQUENCY (MHz)

at 12 bits, and the AD9240,

10M

100M

Rev. C | Page 14 of 16

In this circuit, one of the op amps is configured in the inverting

mode whereas the other is in the noninverting mode. However,

to provide better bandwidth matching, each op amp is configured

for a noise gain of +2. The inverting op amp is configured for a

gain of −1 and the noninverting op amp is configured for a gain

of +2. Each of these produces a noise gain of +2, which is deter-

mined only by the inverse of the feedback ratio. The input signal to

the noninverting op amp is divided by two to normalize its level

and make it equal to the inverting output.

For 0 V input, the outputs of the op amps want to be at 2.5 V,

which is the midsupply level of the ADCs. This is accomplished by

first taking the 2.5 V reference output of the ADC and dividing it

by two by a pair of 1 kΩ resistors. The resulting 1.25 V is applied to

the positive input of each op amp. This voltage is then multiplied by

the gain of +2 of the op amps to provide a 2.5 V level at each output.

The assumption for this circuit is that the input signal is bipolar

with respect to ground and the circuit must be dc-coupled thereby

implying the existence of a negative supply elsewhere in the system.

This circuit uses −5 V as the negative supply for the AD8058.

Tying the negative supply of the AD8058 to ground causes a

problem at the input of the noninverting op amp. The input

common-mode voltage can only go to within 1 V of the negative

rail. Because this circuit requires that the positive inputs operate

with a 1.25 V bias, there is not enough room to swing this voltage

in the negative direction. The inverting stage does not have this

problem because its common-mode input voltage remains fixed

at 1.25 V. If dc coupling is not required, various ac coupling

techniques can be used to eliminate this problem.

LAYOUT

The AD8057 and AD8058 are high speed op amps for use in a

board layout that follows standard high speed design rules. Make

all signal traces as short and direct as possible. In particular, keep

the parasitic capacitance on the inverting input of each device

to a minimum to avoid excessive peaking and other undesirable

performance. Bypass the power supplies very close to the power pins

of the package with a 0.1 µF capacitor in parallel with a larger

(approximately 10 µF) tantalum capacitor. Connect these capacitors

to a ground plane that either is on an inner layer or fills the area

of the board that is not used for other signals.

Figure 48. Schematic Circuit for Driving AD9225

1kΩ

AD8058

–5V

+5V

1kΩ

0.1µF

1kΩ

10µF

50Ω

0.1µF

VINA

VINB

+2.5V

10µF

AD9225

REF

+5V

AD8057AR-REEL Analog Devices Inc, AD8057AR-REEL Datasheet - Page 14

AD8057AR-REEL

Specifications of AD8057AR-REEL

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