LMH6715MAX/NOPB National Semiconductor, LMH6715MAX/NOPB Datasheet - Page 10

LMH6715MAX/NOPB

Manufacturer Part Number

LMH6715MAX/NOPB

Description

'IC OP AMP VID DUAL 8-SOIC

Manufacturer

National Semiconductor

Series

PowerWise®, VIP10™r

Datasheet

1.LMH6715MANOPB.pdf (12 pages)

Specifications of LMH6715MAX/NOPB

Applications

Current Feedback

Number Of Circuits

-3db Bandwidth

400MHz

Slew Rate

1300 V/µs

Current - Supply

5.8mA

Current - Output / Channel

70mA

Voltage - Supply, Single/dual (±)

10 V ~ 12 V, ±5 V ~ 6 V

Mounting Type

Surface Mount

Package / Case

8-SOIC (0.154", 3.90mm Width)

Number Of Channels

Voltage Gain Db

60 dB

Common Mode Rejection Ratio (min)

50 dB

Input Offset Voltage

6 mV at +/- 5 V

Supply Current

15.2 mA at +/- 5 V

Maximum Operating Temperature

+ 85 C

Maximum Dual Supply Voltage

+/- 6 V

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

LMH6715MAX

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Application Introduction

has a typical short term settling time to 0.05% of 12ns for a

2V step. Also, the amplifier is virtually free of any long term

thermal tail effects at low gains.

When measuring settling time, a solid ground plane should

be used in order to reduce ground inductance which can

cause common-ground-impedance coupling. Power supply

and ground trace parasitic capacitances and the load ca-

pacitance will also affect settling time.

Placing a series resistor (R

mended for optimal settling time performance when driving a

capacitive load. The Typical Performance plot labeled “R

and Settling Time vs. Capacitive Load” provides a means for

selecting a value of R

DC & NOISE PERFORMANCE

A current-feedback amplifier’s input stage does not have

equal nor correlated bias currents, therefore they cannot be

canceled and each contributes to the total DC offset voltage

at the output by the following equation:

The input resistance is the resistance looking from the non-

inverting input back toward the source. For inverting DC-

offset calculations, the source resistance seen by the input

resistor R

as a part of the non-inverting gain equation. Application note

OA-7 gives several circuits for DC offset correction. The

noise currents for the inverting and non-inverting inputs are

graphed in the Typical Performance plot labeled “Equivalent

Input Noise”. A more complete discussion of amplifier input-

referred noise and external resistor noise contribution can be

found in OA-12.

DIFFERENTIAL GAIN & PHASE

The LMH6715 can drive multiple video loads with very low

differential gain and phase errors. The Typical Performance

plots labeled “Differential Gain vs. Frequency” and “Differen-

tial Phase vs. Frequency” show performance for loads from

1 to 4. The Electrical Characteristics table also specifies

performance for one 150Ω load at 4.43MHz. For NTSC

video, the performance specifications also apply. Application

note OA-24 “Measuring and Improving Differential Gain &

Differential Phase for Video”, describes in detail the tech-

niques used to measure differential gain and phase.

I/O VOLTAGE & OUTPUT CURRENT

The usable common-mode input voltage range (CMIR) of

the LMH6715 specified in the Electrical Characteristics table

of the data sheet shows a range of

this range will cause the input stage to saturate and clip the

output signal.

The output voltage range is determined by the load resistor

and the choice of power supplies. With

output driver will typically drive

of 100Ω. Increasing the supply voltages will change the

common-mode input and output voltage swings while at the

same time increase the internal junction temperature.

must be included in the output offset calculation

for a given capacitive load.

) at the output pin is recom-

3.9V into a load resistance

2.2 volts. Exceeding

5 volts the class A/B

(Continued)

Applications Circuits

SINGLE-TO-DIFFERENTIAL LINE DRIVER

The LMH6715’s well matched AC channel-response allows a

single-ended input to be transformed to highly matched

push-pull driver. From a 1V single-ended input the circuit of

Figure 3 produces 1V differential signal between the two

outputs. For larger signals the input voltage divider (R

DIFFERENTIAL LINE RECEIVER

Figure 4 and Figure 5 show two different implementations of

an instrumentation amplifier which convert differential sig-

nals to single-ended. Figure 5 allows CMRR adjustment

through R

) is necessary to limit the input voltage on channel 2.

FIGURE 3. Single-to-Differential Line Driver

FIGURE 4. Differential Line Receiver

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LMH6715MAX/NOPB National Semiconductor, LMH6715MAX/NOPB Datasheet - Page 10

LMH6715MAX/NOPB

Specifications of LMH6715MAX/NOPB

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