LMH6702MAXNOPB - NATIONAL SEMICONDUCTOR

LMH6682,LMH6683

LMH6682/6683 190MHz Single Supply, Dual and Triple Operational Amplifiers

Literature Number: SNOSA43

LMH6682/6683

190MHz Single Supply, Dual and Triple Operational

Amplifiers

General Description

The LMH6682 and LMH6683 are high speed operational

amplifiers designed for use in modern video systems. These

single supply monolithic amplifiers extend National’s feature-

rich, high value video portfolio to include a dual and a triple

version. The important video specifications of differential

gain (±0.01% typ.) and differential phase (±0.08 degrees)

combined with an output drive current in each amplifier of

85mA make the LMH6682 and LMH6683 excellent choices

for a full range of video applications.

Voltage feedback topology in operational amplifiers assures

maximum flexibility and ease of use in high speed amplifier

designs. The LMH6682/83 is fabricated in National Semicon-

ductor’s VIP10 process. This advanced process provides a

superior ratio of speed to quiescient current consumption

and assures the user of high-value amplifier designs. Ad-

vanced technology and circuit design enables in these am-

plifiers a −3db bandwidth of 190MHz, a slew rate of 940V/

µsec, and stability for gains of less than −1 and greater than

+2.

The input stage design of the LM6682/83 enables an input

signal range that extends below the negative rail. The output

stage voltage range reaches to within 0.8V of either rail

when driving a 2kΩload. Other attractive features include

fast settling and low distortion. Other applications for these

amplifiers include servo control designs. These applications

are sensitive to amplifiers that exhibit phase reversal when

the inputs exceed the rated voltage range. The LMH6682/83

amplifiers are designed to be immune to phase reversal

when the specified input range is exceeded. See applica-

tions section. This feature makes for design simplicity and

flexibility in many industrial applications.

The LMH6682 dual operational amplifier is offered in minia-

ture surface mount packages, SOIC-8, and MSOP-8. The

LMH6683 triple amplifier is offered in SOIC-14 and TSSOP-

14.

Features

=±5V, T

= 25˚C, R

= 100Ω, A = +2 (Typical values

unless specified)

nDG error 0.01%

nDP error 0.08˚

n−3dB BW (A = +2) 190MHz

nSlew rate (V

=±5V) 940V/µs

nSupply current 6.5mA/amp

nOutput current +80/−90mA

nInput common mode voltage 0.5V beyond V

−

, 1.7V from

nOutput voltage swing (R

=2kΩ) 0.8V from rails

nInput voltage noise (100KHz) 12nV/

Applications

nCD/DVD ROM

nADC buffer amp

nPortable video

nCurrent sense buffer

nPortable communications

Connection Diagrams

SOIC-8/MSOP-8 (LMH6682) SOIC-14/TSSOP-14 (LMH6683)

20059002

Top View

20059003

Top View

November 2002

LMH6682/6683 190MHz Single Supply, Dual and Triple Operational Amplifiers

Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,

please contact the National Semiconductor Sales Office/

Distributors for availability and specifications.

ESD Tolerance

Human Body Model 2KV(Note 2)

Machine Model 200V (Note 3)

Differential ±2.5V

Output Short Circuit Duration (Note 4), (Note 6)

Input Current ±10mA

Supply Voltage (V

-V

−

) 12.6V

Voltage at Input/Output pins V

+0.8V, V

−

−0.8V

Soldering Information

Infrared or Convection (20 sec.) 235˚C

Wave Soldering (10 sec.) 260˚C

Storage Temperature Range −65˚C to +150˚C

Junction Temperature (Note 7) +150˚C

Operating Ratings (Note 1)

Supply Voltage (V

–V

−

) 3Vto12V

Operating Temperature Range

(Note 7) −40˚C to +85˚C

Package Thermal Resistance (Note 7)

SOIC-8 190˚C/W

MSOP-8 235˚C/W

SOIC-14 145˚C/W

TSSOP-14 155˚C/W

5V Electrical Characteristics

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= 0V, V

/2, and R

= 100Ωto V

/2,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

SSBW −3dB BW A = +2, V

OUT

= 200mV

140 180 MHz

A = −1, V

OUT

= 200mV

180

GFP Gain Flatness Peaking A = +2, V

OUT

= 200mV

DC to 100MHz

2.1 dB

GFR Gain Flatness Rolloff A = +2, V

OUT

= 200mV

DC to 100MHz

0.1 dB

LPD 1˚ 1˚ Linear Phase Deviation A = +2, V

OUT

= 200mV

,±1˚ 40 MHz

0.1dB

0.1dB Gain Flatness A = +2, ±0.1dB, V

OUT

= 200mV

25 MHz

FPBW Full Power −1dB Bandwidth A = +2, V

OUT

=2V

110 MHz

DG Differential Gain

NTSC 3.58MHz

A = +2, R

= 150Ωto V

Pos video only V

=2V

0.03 %

DP Differential Phase

NTSC 3.58MHz

A = +2, R

= 150Ωto V

Pos video only V

=2V

0.05 deg

Time Domain Response

Rise and Fall Time 20-80%, V

=1V

= +2 2.1 ns

20-80%, V

=1V

=−1 2

OS Overshoot A = +2, V

= 100mV

22 %

Settling Time V

=2V

,±0.1%, A

=+2 49 ns

SR Slew Rate (Note 11) A = +2, V

OUT

=3V

520 V/µs

A = −1, V

OUT

=3V

500

Distortion and Noise Response

HD2 2

Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−60

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−61

HD3 3

Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−77

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−54

LMH6682/6683

www.national.com 2

5V Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= 0V, V

/2, and R

= 100Ωto V

/2,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

Distortion and Noise Response

THD Total Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−60

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−53

Input Referred Voltage Noise f = 1kHz 17 nV/

f = 100kHz 12

Input Referred Current Noise f = 1kHz 8 pA/

f = 100kHz 3

CT Cross-Talk Rejection

(Amplifier)

f = 5MHz, A = +2, SND: R

= 100Ω

RCV: R

= 510Ω

−77 dB

Static, DC Performance

VOL

Large Signal Voltage Gain V

= 1.25V to 3.75V,

=2kΩto V

85 95

= 1.5V to 3.5V,

= 150Ωto V

75 85

=2Vto3V,

=50Ωto V

70 80

CMVR Input Common-Mode Voltage

Range

CMRR ≥50dB −0.2

−0.1

−0.5

3.0

2.8

3.3

Input Offset Voltage ±1.1 ±5

±7mV

TC V

Input Offset Voltage Average

Drift

(Note 12) ±2 µV/˚C

Input Bias Current (Note 10) −5 −20

−30 µA

Input Bias Current Drift 0.01 nA/˚C

Input Offset Current 50 300

500 nA

CMRR Common Mode Rejection

Ratio

Stepped from 0V to 3.0V 72 82 dB

+PSRR Positive Power Supply

Rejection Ratio

= 4.5V to 5.5V, V

=1V 70 76 dB

Supply Current (per channel) No load 6.5 9

11 mA

LMH6682/6683

www.national.com3

5V Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= 0V, V

/2, and R

= 100Ωto V

/2,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

Miscellaneous Performance

Output Swing

High

=2kΩto V

/2 4.10

3.8

4.25

= 150Ωto V

/2 3.90

3.70

4.19

=75Ωto V

/2 3.75

3.50

4.15

Output Swing

Low

=2kΩto V

/2 800 920

1100

= 150Ωto V

/2 870 970

1200

=75Ωto V

/2 885 1100

1250

OUT

Output Current V

= 1V from either supply rail ±40 +80/−75 mA

Output Short Circuit Current

(Note 5), (Note 6), (Note 10)

Sourcing to V

/2 −100

−80

−155

Sinking from V

/2 100

220

Common Mode Input

Resistance

3MΩ

Common Mode Input

Capacitance

1.6 pF

OUT

Output Resistance Closed

Loop

f = 1kHz, A = +2, R

=50Ω0.02 Ω

f = 1MHz, A = +2, R

=50Ω0.12

±5V Electrical Characteristics

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= −5V, V

= 0V, and R

= 100Ωto 0V,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

SSBW −3dB BW A = +2, V

OUT

= 200mV

150 190 MHz

A = −1, V

OUT

= 200mV

190

GFP Gain Flatness Peaking A = +2, V

OUT

= 200mV

DC to 100MHz

1.7 dB

GFR Gain Flatness Rolloff A = +2, V

OUT

= 200mV

DC to 100MHz

0.1 dB

LPD 1˚ 1˚ Linear Phase Deviation A = +2, V

OUT

= 200mV

,±1˚ 40 MHz

0.1dB

0.1dB Gain Flatness A = +2, ±0.1dB, V

OUT

= 200mV

25 MHz

FPBW Full Power −1dB Bandwidth A = +2, V

OUT

=2V

120 MHz

DG Differential Gain

NTSC 3.58MHz

A = +2, R

= 150Ωto 0V 0.01 %

DP Differential Phase

NTSC 3.58MHz

A = +2, R

= 150Ωto 0V 0.08 deg

Time Domain Response

Rise and Fall Time 20-80%, V

=1V

,A=+2 1.9 ns

20-80%, V

=1V

,A=−1 2

OS Overshoot A = +2, V

= 100mV

19 %

Settling Time V

=2V

,±0.1%, A = +2 42 ns

LMH6682/6683

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±5V Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= −5V, V

= 0V, and R

= 100Ωto 0V,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

Time Domain Response

SR Slew Rate (Note 11) A = +2, V

OUT

=6V

940 V/µs

A = −1, V

OUT

=6V

900

Distortion and Noise Response

HD2 2

Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−63

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−66

HD3 3

Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−82

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−54

THD Total Harmonic Distortion f = 5MHz, V

=2V

, A = +2, R

2kΩ

−63

dBc

f = 5MHz, V

=2V

, A = +2, R

100Ω

−54

Input Referred Voltage Noise f = 1kHz 18 nV/

f = 100kHz 12

Input Referred Current Noise f = 1kHz 6 pA/

f = 100kHz 3

CT Cross-Talk Rejection

(Amplifier)

f = 5MHz, A = +2, SND: R

= 100Ω

RCV: R

= 510Ω

−78 dB

Static, DC Performance

VOL

Large Signal Voltage Gain V

= −3.75V to 3.75V,

=2kΩto V

87 100

= −3.5V to 3.5V,

= 150Ωto V

80 90

= −3V to 3V,

=50Ωto V

75 85

CMVR Input Common Mode Voltage

Range

CMRR ≥50dB −5.2

−5.1

−5.5

3.0

2.8

3.3

Input Offset Voltage ±1±5

±7mV

TC V

Input Offset Voltage Average

Drift

(Note 12) ±2 µV/˚C

Input Bias Current (Note 10) −5 −20

−30 µA

Input Bias Current Drift 0.01 nA/˚C

Input Offset Current 50 300

500 nA

CMRR Common Mode Rejection

Ratio

Stepped from −5V to 3.0V 75 84 dB

+PSRR Positive Power Supply

Rejection Ratio

= 8.5V to 9.5V,

−

= −1V

75 82 dB

−PSRR Negative Power Supply

Rejection Ratio

−

= −4.5V to −5.5V,

=5V

78 85 dB

LMH6682/6683

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±5V Electrical Characteristics (Continued)

Unless otherwise specified, all limits guaranteed for at T

= 25˚C, V

= 5V, V

−

= −5V, V

= 0V, and R

= 100Ωto 0V,

= 510Ω.Boldface limits apply at the temperature extremes.

Symbol Parameter Conditions Min

(Note 9)

Typ

(Note 8)

Max

(Note 9)

Units

Static, DC Performance

Supply Current (per channel) No load 6.5 9.5

11 mA

Miscellaneous Performance

Output Swing

High

=2kΩto 0V 4.10

3.80

4.25

= 150Ωto 0V 3.90

3.70

4.20

=75Ωto 0V 3.75

3.50

4.18

Output Swing

Low

=2kΩto 0V −4.19 −4.07

−3.80

= 150Ωto 0V −4.05 −3.89

−3.65

=75Ωto 0V −4.00 −3.70

−3.50

OUT

Output Current V

= 1V from either supply rail ±45 +85/−80 mA

Output Short Circuit Current

(Note 5) , (Note 6),(Note 10)

Sourcing to 0V −120

−100

−180

Sinking from 0V 120

100

230

Common Mode Input

Resistance

4MΩ

Common Mode Input

Capacitance

1.6 pF

OUT

Output Resistance Closed

Loop

f = 1kHz, A = +2, R

=50Ω0.02 Ω

f = 1MHz, A = +2, R

=50Ω0.12

Note 1: Absolute maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is

intended to be functional, but specific performance is not guaranteed. For guaranteed specifications and the test conditions, see the Electrical Characteristics.

Note 2: Human body model, 1.5kΩin series with 100pF.

Note 3: Machine Model, 0Ωin series with 200pF.

Note 4: Applies to both single-supply and split-supply operation. Continuous short circuit operation at elevated ambient temperature can result in exceeding the

maximum allowed junction temperature of 150˚C.

Note 5: Short circuit test is a momentary test. See next note.

Note 6: Output short circuit duration is infinite for VS<6V at room temperature and below. For VS>6V, allowable short circuit duration is 1.5ms.

Note 7: The maximum power dissipation is a function of TJ(MAX),θJA, and TA. The maximum allowable power dissipation at any ambient temperature is

PD=(T

J(MAX) -T

A)/ θJA . All numbers apply for packages soldered directly onto a PC board.

Note 8: Typical values represent the most likely parametric norm.

Note 9: All limits are guaranteed by testing or statistical analysis.

Note 10: Positive current corresponds to current flowing into the device.

Note 11: Slew rate is the average of the rising and falling slew rates

Note 12: Offset Voltage average drift determined by dividing the change in VOS at temperature extremes into the total temperature change.

LMH6682/6683

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Typical Schematic

20059001

Ordering Information

Package Part Number Package Marking Transport Media NSC Drawing

8-Pin SOIC LMH6682MA LMH6682MA 95 Units/Rail M08A

LMH6682MAX 2.5k Units Tape and Reel

8-Pin MSOP LMH6682MM A90A 1k Units Tape and Reel MUA08A

LMH6682MMX 2.5k Units Tape and Reel

14-Pin SOIC LMH6683MA LMH6683MA 55 Units/Rail M14A

LMH6683MAX 2.5k Units Tape and Reel

14-Pin

TSSOP

LMH6683MT LMH6683MT 94 Units/Rail MTC14

LMH6683MTX 2.5 Units Tape and Reel

LMH6682/6683

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Typical Performance Characteristics

At T

= 25˚C, V

= +5V, V

−

= −5V, R

= 510Ωfor A = +2; unless otherwise specified.

Non-Inverting Frequency Response Inverting Frequency Response

20059004 20059006

Non-Inverting Frequency Response for Various Gain Inverting Frequency Response for Various Gain

20059005 20059007

Non-Inverting Phase vs. Frequency for Various Gain Inverting Phase vs. Frequency for Various Gain

20059024 20059025

LMH6682/6683

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Typical Performance Characteristics (Continued)

Open Loop Gain & Phase vs. Frequency

Open Loop Gain and Phase vs. Frequency Over

Temperature

20059008 20059057

Non-Inverting Frequency Response Over Temperature Inverting Frequency Response Over Temperature

20059038 20059037

Gain Flatness 0.1dB Differential Gain & Phase for A = +2

20059009 20059013

LMH6682/6683

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Typical Performance Characteristics (Continued)

Transient Response Negative Transient Response Positive

20059012 20059010

Noise vs. Frequency Noise vs. Frequency

20059039 20059020

Harmonic Distortion vs. V

OUT

Harmonic Distortion vs. V

OUT

20059045 20059044

LMH6682/6683

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Typical Performance Characteristics (Continued)

Harmonic Distortion vs. V

OUT

THD vs. for Various Frequencies

20059043 20059042

Harmonic Distortion vs. Frequency Crosstalk vs. Frequency

20059046 20059014

OUT

vs. Frequency I

vs. V

SUPPLY

Over Temperature

20059021

20059023

LMH6682/6683

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Typical Performance Characteristics (Continued)

vs. V

@−40˚C V

vs. V

@25˚C

20059047 20059048

vs. V

@85˚C V

vs. V

@125˚C

20059049 20059050

vs. V

OUT

vs. V

OUT

20059035 20059036

LMH6682/6683

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Typical Performance Characteristics (Continued)

SUPPLY

/Amp vs. V

SUPPLY

/Amp vs. V

SUPPLY

20059030 20059026

OUT

vs. I

SOURCE

OUT

vs. I

SINK

20059031 20059033

OUT

vs. I

SOURCE

OUT

vs. I

SINK

20059032 20059034

LMH6682/6683

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Typical Performance Characteristics (Continued)

vs. V

|vs. V

20059028 20059064

Short Circuit I

SOURCE

vs. V

Short Circuit I

SINK

vs. V

20059059 20059058

Linearity Input vs. Output Linearity Input vs. Output

20059041 20059040

LMH6682/6683

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Typical Performance Characteristics (Continued)

CMRR vs. Frequency PSRR vs. Frequency

20059022 20059011

Small Signal Pulse Response for A = +2 Small Signal Pulse Response A = −1

20059015 20059016

Large Signal Pulse Response Large Signal Pulse Response

20059017 20059018

LMH6682/6683

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Applications Section

LARGE SIGNAL BEHAVIOR

Amplifying high frequency signals with large amplitudes (as

in video applications) has some special aspects to look after.

The bandwidth of the Op Amp for large amplitudes is less

than the small signal bandwidth because of slew rate limita-

tions. While amplifying pulse shaped signals the slew rate

properties of the OpAmp become more important at higher

amplitude ranges. Due to the internal structure of an Op Amp

the output can only change with a limited voltage difference

per time unit (dV/dt). This can be explained as follows: To

keep it simple, assume that an Op Amp consists of two parts;

the input stage and the output stage. In order to stabilize the

Op Amp, the output stage has a compensation capacitor in

its feedback path. This Miller C integrates the current from

the input stage and determines the pulse response of the Op

Amp. The input stage must charge/discharge the feedback

capacitor, as can be seen in Figure 1.

When a voltage transient is applied to the non inverting input

of the Op Amp, the current from the input stage will charge

the capacitor and the output voltage will slope up. The

overall feedback will subtract the gradually increasing output

voltage from the input voltage. The decreasing differential

input voltage is converted into a current by the input stage

(Gm).

I*∆t=C*∆V (1)

∆V/∆t = I/C (2)

I=∆V*Gm (3)

where I = current

t = time

C = capacitance

V = voltage

Gm = transconductance

Slew rate ∆V/∆t = volt/second

In most amplifier designs the current I is limited for high

differential voltages (Gm becomes zero). The slew rate will

than be limited as well:

∆V/∆t = Imax/C (4)

The LMH6682/83 has a different setup of the input stage. It

has the property to deliver more current to the output stage

when the input voltage is higher (class AB input). The current

into the Miller capacitor exhibits an exponential character,

while this current in other Op Amp designs reaches a satu-

ration level at high input levels: (see Figure 2)

This property of the LMH6682/83 guaranties a higher slew

rate at higher differential input voltages.

∆V/∆t=∆V*Gm/C (5)

In Figure 3 one can see that a higher transient voltage than

will lead to a higher slew rate.

HANDLING VIDEO SIGNALS

When handling video signals, two aspects are very important

especially when cascading amplifiers in a NTSC- or PAL

video system. A composite video signal consists of both

amplitude and phase information. The amplitude represents

saturation while phase determines color (color burst is

3.59MHz for NTSC and 4.58MHz for PAL systems). In this

case it is not only important to have an accurate amplification

of the amplitude but also it is important not to add a varying

phase shift to the video signals. It is a known phenomena

that at different dc levels over a certain load the phase of the

amplified signal will vary a little bit. In a video chain many

amplifiers will be cascaded and all errors will be added

together. For this reason, it is necessary to have strict re-

quirements for the variation in gain and phase in conjunction

to different dc levels. As can be seen in the tables the

number for the differential gain for the LMH6682/83 is only

0.01% and for the differential phase it is only 0.08˚ at a

supply voltage of ±5V. Note that the phase is very depen-

20059060

FIGURE 1.

20059061

FIGURE 2.

20059062

FIGURE 3.

LMH6682/6683

www.national.com 16

Applications Section (Continued)

dent of the load resistance, mainly because of the dc current

delivered by the parts output stage into the load. For more

information about differential gain and phase and how to

measure it see National Semiconductors application note

OA-24 which can be found on via Nationals home page

http://www.national.com

OUTPUT PHASE REVERSAL

This is a problem with some operational amplifiers. This

effect is caused by phase reversal in the input stage due to

saturation of one or more of the transistors when the inputs

exceed the normal expected range of voltages. Some appli-

cations, such as servo control loops among others, are

sensitive to this kind of behavior and would need special

safeguards to ensure proper functioning. The LMH6682/

6683 is immune to output phase reversal with input overload.

With inputs exceeded, the LMH6682/6683 output will stay at

the clamped voltage from the supply rail. Exceeding the

input supply voltages beyond the Absolute Maximum Rat-

ings of the device could however damage or otherwise ad-

versely effect the reliability or life of the device.

DRIVING CAPACITIVE LOADS

The LMH6682/6683 can drive moderate values of capaci-

tance by utilizing a series isolation resistor between the

output and the capacitive load. Capacitive load tolerance will

improve with higher closed loop gain values. Applications

such as ADC buffers, among others, present complex and

varying capacitive loads to the Op Amp; best value for this

isolation resistance is often found by experimentation and

actual trial and error for each application.

DISTORTION

Applications with demanding distortion performance require-

ments are best served with the device operating in the

inverting mode. The reason for this is that in the inverting

configuration, the input common mode voltage does not vary

with the signal and there is no subsequent ill effects due to

this shift in operating point and the possibility of additional

non-linearity. Moreover, under low closed loop gain settings

(most suited to low distortion), the non-inverting configura-

tion is at a further disadvantage of having to contend with the

input common voltage range. There is also a strong relation-

ship between output loading and distortion performance (i.e.

2kΩvs. 100Ωdistortion improves by about 15dB @1MHz)

especially at the lower frequency end where the distortion

tends to be lower. At higher frequency, this dependence

diminishes greatly such that this difference is only about 5dB

at 10MHz. But, in general, lighter output load leads to re-

duced HD3 term and thus improves THD. (see the curve

THD vs. V

OUT

over various frequencies).

PRINTED CIRCUIT BOARD LAYOUT AND COMPONENT

VALUES SELECTION

Generally it is a good idea to keep in mind that for a good

high frequency design both the active parts and the passive

ones are suitable for the purpose you are using them for.

Amplifying frequencies of several hundreds of MHz is pos-

sible while using standard resistors but it makes life much

easier when using surface mount ones. These resistors (and

capacitors) are smaller and therefore parasitics have lower

values and will have less influence on the properties of the

amplifier. Another important issue is the PCB, which is no

longer a simple carrier for all the parts and a medium to

interconnect them. The board becomes a real part itself,

adding its own high frequency properties to the overall per-

formance of the circuit. It’s good practice to have at least one

ground plane on a PCB giving a low impedance path for all

decouplings and other ground connections. Care should be

taken especially that on board transmission lines have the

same impedance as the cables they are connected to (i.e.

50Ωfor most applications and 75Ωin case of video and

cable TV applications). These transmission lines usually re-

quire much wider traces on a standard double sided PCB

than needed for a ’normal’ connection. Another important

issue is that inputs and outputs must not ’see’ each other or

are routed together over the PCB at a small distance. Fur-

thermore it is important that components are placed as flat

as possible on the surface of the PCB. For higher frequen-

cies a long lead can act as a coil, a capacitor or an antenna.

A pair of leads can even form a transformer. Careful design

of the PCB avoids oscillations or other unwanted behavior.

When working with really high frequencies, the only compo-

nents which can be used will be the surface mount ones (for

more information see OA-15).

As an example of how important the component values are

for the behavior of your circuit, look at the following case: On

a board with good high frequency layout, an amplifier is

placed. For the two (equal) resistors in the feedback path, 5

different values are used to set the gain to +2. The resistors

vary from 200Ωto 3kΩ.

In Figure 4 can be seen that there’s more peaking with

higher resistor values, which can lead to oscillations and bad

pulse responses. On the other hand the low resistor values

will contribute to higher overall power consumption.

NSC suggests the following evaluation boards as a guide for

high frequency layout and as an aid in device testing and

characterization.

Device Package Evaluation

Board PN

LMH6682MA 8-Pin SOIC CLC730036

LMH6682MM 8-Pin MSOP CLC730123

LMH6683MA 14-Pin SOIC CLC730031

LMH6683MT 14-Pin TSSOP CLC730131

These free evaluation boards are shipped when a device

sample request is placed with National Semiconductor.

20059063

FIGURE 4.

LMH6682/6683

www.national.com17

Physical Dimensions inches (millimeters) unless otherwise noted

8-Pin SOIC

NS Package Number M08A

8-Pin MSOP

NS Package Number MUA08A

LMH6682/6683

www.national.com 18

Physical Dimensions inches (millimeters) unless otherwise noted (Continued)

14-Pin SOIC

NS Package Number M14A

14-Pin TSSOP

NS Package Number MTC14

LMH6682/6683

www.national.com19

Notes

LIFE SUPPORT POLICY

NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT

DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL

COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:

1. Life support devices or systems are devices or

systems which, (a) are intended for surgical implant

into the body, or (b) support or sustain life, and

whose failure to perform when properly used in

accordance with instructions for use provided in the

labeling, can be reasonably expected to result in a

significant injury to the user.

2. A critical component is any component of a life

support device or system whose failure to perform

can be reasonably expected to cause the failure of

the life support device or system, or to affect its

safety or effectiveness.

National Semiconductor

Corporation

Americas

Email: support@nsc.com

National Semiconductor

Europe

Fax: +49 (0) 180-530 85 86

Email: europe.support@nsc.com

Deutsch Tel: +49 (0) 69 9508 6208

English Tel: +44 (0) 870 24 0 2171

Français Tel: +33 (0) 1 41 91 8790

National Semiconductor

Asia Pacific Customer

Response Group

Tel: 65-2544466

Fax: 65-2504466

Email: ap.support@nsc.com

National Semiconductor

Japan Ltd.

Tel: 81-3-5639-7560

Fax: 81-3-5639-7507

www.national.com

LMH6682/6683 190MHz Single Supply, Dual and Triple Operational Amplifiers

National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.

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