AD8436-EVALZ Analog Devices, AD8436-EVALZ Datasheet - Page 11

AD8436-EVALZ

Manufacturer Part Number

AD8436-EVALZ

Description

Power Management IC Development Tools Eval Board

Manufacturer

Analog Devices

Type

Other Power Managementr

Series

AD8436r

Datasheet

1.AD8436-EVALZ.pdf (24 pages)

Specifications of AD8436-EVALZ

Rohs

yes

Product

Evaluation Boards

Tool Is For Evaluation Of

AD8436

Input Voltage

+ / - 18 V

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 40 C

Factory Pack Quantity

Current page: 11 of 24
Download datasheet (740Kb)

Data Sheet

The 16 kΩ resistor in the output converts the output current to

a dc voltage that can be connected to the output buffer or to the

circuit that follows. The output appears as a voltage source in

series with 16 kΩ. If a current output is desired, the resistor

connection to ground is left open and the output current is

applied to a subsequent circuit, such as the summing node of

a current summing amplifier. Thus, the core has both current

and voltage outputs, depending on the configuration. For a

voltage output with 0 Ω source impedance, use the output

buffer. The offset voltage of the buffer is 25 μV or 50 μV,

depending on the grade.

FET Input Buffer

Because the V-to-I input resistor value of the

is 8 kΩ, a high input impedance buffer is often used between

rms-dc converters and finite impedance sources. The optional

JFET input op amp minimizes attenuation and uncouples

common input amenities, such as resistive voltage dividers or

resistors used to terminate current transformers. The wide

bandwidth of the FET buffer is well matched to the rms core

bandwidth so that no information is lost due to serial band-

width effects. Although the input buffer consumes little current,

the buffer supply is independently accessible and can be

disconnected to reduce power.

Optional matched 10 kΩ input and feedback resistors are provided

on chip. Consult the Applications Information section to learn

how these resistors can be used. The 3 dB bandwidth of the input

buffer is 2.7 MHz at 10 mV rms input and approximately 1.5 MHz

at 1 V rms. The amplifier gain and bandwidth are sufficient for

applications requiring modest gain or response enhancement to

a few hundred kilohertz (kHz), if desired. Configurations of the

input buffer are discussed in the Applications Information

section.

Precision Output Buffer

The precision output buffer is a bipolar input amplifier, laser

trimmed to cancel input offset voltage errors. As with the input

buffer, the supply current is very low (<50 μA, typically), and the

power can be disconnected for power savings if the buffer is not

needed. Be sure that the noninverting input is also disconnected

from the core output (OUT) if the buffer supply pin is discon-

nected. Although the input current of the buffer is very low,

a laser-trimmed 16 kΩ resistor, connected in series with the

inverting input, offsets any self-bias offset voltage.

AD8436

rms core

Rev. B | Page 11 of 24

The output buffer can be configured as a single or two-pole low-

pass filter using circuits shown in the Applications Information

section. Residual output ripple is reduced, without affecting the

converted dc output. As the response approaches the low

frequency end of the bandwidth, the ripple rises, dependent on

the value of the averaging capacitor. Figure 27 shows the effects of

four combinations of averaging and filter capacitors. Although

the filter capacitor reduces the ripple for any given frequency, the

dc error is unaffected. Of course, a larger value averaging

capacitor can be selected, at a larger cost. The advantage of using

a low-pass filter is that a small value of filter capacitor, in

conjunction with the 16 kΩ output resistor, reduces ripple and

permits a smaller averaging capacitor, effecting a cost savings.

The recommended capacitor values for operation to 40 Hz are

10 µF for averaging and 3.3 µF for filter.

Dynamic Range

The

dynamic range. Although accuracy varies slightly more at the

extreme input values, the device still converts with no spurious

noise or dropout. Figure 25 is a plot of the rms/dc transfer function

near zero voltage. Unlike processor or other solutions, residual

errors at very low input levels can be disregarded for most

applications.

–30

AD8436

is a translinear rms-to-dc converter with exceptional

–20

SOLUTION

Figure 25. DC Transfer Function near Zero

AD8436

–10

INPUT VOLTAGE (mV DC)

ΔΣ OR OTHER DIGITAL

SOLUTIONS CANNOT

WORK AT ZERO

VOLTS

AD8436

AD8436-EVALZ Analog Devices, AD8436-EVALZ Datasheet - Page 11

AD8436-EVALZ

Specifications of AD8436-EVALZ

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