REV. B

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties that
may result from its use. No license is granted by implication or otherwise
under any patent or patent rights of Analog Devices.

AD8132

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700

www.analog.com

Fax: 781/326-8703

© Analog Devices, Inc., 2002

Low-Cost, High-Speed

Differential Amplifier

FUNCTIONAL BLOCK DIAGRAM

AD8132

NC = NO CONNECT

IN

+IN

OCM

V+

+OUT

OUT

FEATURES
High Speed

350 MHz 3 dB Bandwidth
1200 V/ s Slew Rate

Resistor-Settable Gain
Internal Common-Mode Feedback to Improve Gain

and Phase Balance 68 dB @ 10 MHz

Separate Input to Set the Common-Mode Output

Voltage

Low Distortion 99 dBc SFDR @ 5 MHz 800 Load
Low Power 10.7 mA @ 5 V
Power Supply Range +2.7 V to 5.5 V

APPLICATIONS
Low Power Differential ADC Driver
Differential Gain and Differential Filtering
Video Line Driver
Differential In/Out Level-Shifting
Single-Ended Input to Differential Output Driver
Active Transformer

GENERAL DESCRIPTION

The AD8132 is a low-cost differential or single-ended input to
differential output amplifier with resistor-settable gain. The
AD8132 is a major advancement over op amps for driving
differential input ADCs or for driving signals over long lines.
The AD8132 has a unique internal feedback feature that pro-
vides output gain and phase matching balanced to 68 dB at
10 MHz, suppressing harmonics, and reducing radiated EMI.

Manufactured on ADI's next generation of XFCB bipolar
process, the AD8132 has a 3 dB bandwidth of 350 MHz and
delivers a differential signal with 99 dBc SFDR at 5 MHz,
despite its low cost. The AD8132 eliminates the need for a
transformer with high-performance ADCs, preserving the low
frequency and dc information. The common-mode level of the
differential output is adjustable by applying a voltage on the V

OCM

pin, easily level-shifting the input signals for driving single supply
ADCs. Fast overload recovery preserves sampling accuracy.

The AD8132 can also be used as a differential driver for the
transmission of high-speed signals over low-cost twisted pair or
coaxial cables. The feedback network can be adjusted to boost
the high-frequency components of the signal. The AD8132 can
be used for either analog or digital video signals or for other
high-speed data transmission. The AD8132 is capable of driving
either cat3 or cat5 twisted pair or coaxial with minimal line
attenuation. The AD8132 has considerable cost and performance
improvements over discrete line driver solutions.

Differential signal processing reduces the effects of ground noise
which plagues ground referenced systems. The AD8132 can be used
for differential signal processing (gain and filtering) throughout a
signal chain, easily simplifying the conversion between differential
and single-ended components.

The AD8132 is available in both SOIC and

µSOIC packages for

operation over 40

°C to +85°C temperatures.

FREQUENCY MHz

GAIN

12

100

= 5V

G = 1
V

O,dm

= 2V p-p

L,dm

= 499

Figure 1. Large Signal Frequency Response

REV. B

AD8132SPECIFICATIONS

arameter

Conditions

Min

Typ

Max

Unit

to OUT Specifications

DYNAMIC PERFORMANCE

3 dB Large Signal Bandwidth

OUT

= 2 V p-p

300

350

MHz

OUT

= 2 V p-p, G = 2

190

MHz

3 dB Small Signal Bandwidth

OUT

= 0.2 V p-p

360

MHz

OUT

= 0.2 V p-p, G = 2

160

MHz

Bandwidth for 0.1 dB Flatness

OUT

= 0.2 V p-p

MHz

OUT

= 0.2 V p-p, G = 2

MHz

Slew Rate

OUT

= 2 V p-p

1000

1200

µs

Settling Time

0.1%, V

OUT

= 2 V p-p

Overdrive Recovery Time

= 5 V to 0 V Step, G = 2

NOISE/HARMONIC PERFORMANCE

Second Harmonic

OUT

= 2 V p-p, 1 MHz, R

L,dm

= 800

dBc

OUT

= 2 V p-p, 5 MHz, R

L,dm

= 800

dBc

OUT

= 2 V p-p, 20 MHz, R

L,dm

= 800

dBc

Third Harmonic

OUT

= 2 V p-p, 1 MHz, R

L,dm

= 800

102

dBc

OUT

= 2 V p-p, 5 MHz, R

L,dm

= 800

dBc

OUT

= 2 V p-p, 20 MHz, R

L,dm

= 800

dBc

IMD

20 MHz, R

L,dm

= 800

dBc

IP3

20 MHz, R

L,dm

= 800

dBm

Input Voltage Noise (RTI)

f = 0.1 MHz to 100 MHz

nV/

Input Current Noise

f = 0.1 MHz to 100 MHz

1.8

pA/

Differential Gain Error

NTSC, G = 2, R

L,dm

= 150

0.01

Differential Phase Error

NTSC, G = 2, R

L,dm

= 150

0.10

Degrees

INPUT CHARACTERISTICS

Offset Voltage (RTI)

OS,dm

= V

OUT,dm

/2; V

DIN+

= V

DIN

= V

OCM

= 0 V

±1.0

±3.5

MIN

to T

MAX

Variation

µV/°C

Input Bias Current

µA

Input Resistance

Differential

Common-Mode

3.5

Input Capacitance

Input Common-Mode Voltage

7 to +6

CMRR

OUT,dm

IN,cm

;

IN,cm

±1 V;

Resistors Matched to 0.01%

OUTPUT CHARACTERISTICS

Output Voltage Swing

Maximum

OUT

; Single-Ended Output

3.6 to +3.6

Output Current

Output Balance Error

OUT,cm

OUT,dm

;

OUT,dm

= 1 V

OCM

to OUT Specifications

DYNAMIC PERFORMANCE

3 dB Bandwidth

OCM

= 600 mV p-p

210

MHz

Slew Rate

OCM

= 1 V to +1 V

400

µs

DC PERFORMANCE

Input Voltage Range

±3.6

Input Resistance

150

Input Offset Voltage

OS,cm

= V

OUT,cm

; V

DIN+

= V

DIN

= V

OCM

= 0 V

±1.5

±7

Input Bias Current

0.5

µA

OCM

CMRR

OUT,dm

OCM

];

OCM

±1 V;

Resistors Matched to 0.01%

Gain

OUT,cm

OCM

;

OCM

±1 V

0.985

1.015

V/V

POWER SUPPLY

Operating Range

±1.35

±5.5

Quiescent Current

DIN+

= V

DIN

= V

OCM

= 0 V

MIN

to T

MAX

Variation

µA/°C

Power Supply Rejection Ratio

OUT,dm

;

±1 V

OPERATING TEMPERATURE RANGE

+85

°C

Specifications subject to change without notice.

(@ 25 C, V

= 5 V, V

OCM

= 0 V, G = 1, R

L,dm

= 499 , R

= R

= 348 unless

otherwise noted. For G = 2, R

L,dm

= 200

, R

= 1000

, R

= 499

. Refer to TPC 1 and TPC 10 for test setup and label descriptions. All

specifications refer to single-ended input and differential outputs unless otherwise noted.)

REV. B

AD8132

arameter

Conditions

Min

Typ

Max

Unit

to OUT Specifications

DYNAMIC PERFORMANCE

3 dB Large Signal Bandwidth

OUT

= 2 V p-p

250

300

MHz

OUT

= 2 V p-p, G = 2

180

MHz

3 dB Small Signal Bandwidth

OUT

= 0.2 V p-p

360

MHz

OUT

= 0.2 V p-p, G = 2

155

MHz

Bandwidth for 0.1 dB Flatness

OUT

= 0.2 V p-p

MHz

OUT

= 0.2 V p-p, G = 2

MHz

Slew Rate

OUT

= 2 V p-p

800

1000

µs

Settling Time

0.1%, V

OUT

= 2 V p-p

Overdrive Recovery Time

= 2.5 V to 0 V Step, G = 2

NOISE/HARMONIC PERFORMANCE

Second Harmonic

OUT

= 2 V p-p, 1 MHz, R

L,dm

= 800

dBc

OUT

= 2 V p-p, 5 MHz, R

L,dm

= 800

100

dBc

OUT

= 2 V p-p, 20 MHz, R

L,dm

= 800

dBc

Third Harmonic

OUT

= 2 V p-p, 1 MHz, R

L,dm

= 800

100

dBc

OUT

= 2 V p-p, 5 MHz, R

L,dm

= 800

dBc

OUT

= 2 V p-p, 20 MHz, R

L,dm

= 800

dBc

IMD

20 MHz, R

L,dm

= 800

dBc

IP3

20 MHz, R

L,dm

= 800

dBm

Input Voltage Noise (RTI)

f = 0.1 MHz to 100 MHz

nV/

Input Current Noise

f = 0.1 MHz to 100 MHz

1.8

pA/

Differential Gain Error

NTSC, G = 2, R

L,dm

= 150

0.025

Differential Phase Error

NTSC, G = 2, R

L,dm

= 150

0.15

Degree

INPUT CHARACTERISTICS

Offset Voltage (RTI)

OS,dm

= V

OUT,dm

/2; V

DIN+

= V

DIN

= V

OCM

= 2.5 V

±1.0

±3.5

MIN

to T

MAX

Variation

µV/°C

Input Bias Current

µA

Input Resistance

Differential

Common-Mode

Input Capacitance

Input Common-Mode Voltage

1 to +4

CMRR

OUT,dm

IN,cm

;

IN,cm

±1 V;

Resistors Matched to 0.01%

OUTPUT CHARACTERISTICS

Output Voltage Swing

Maximum

OUT

; Single-Ended Output

1 to 3.7

Output Current

Output Balance Error

OUT,cm

OUT,dm

;

OUT,dm

= 1 V

OCM

to OUT Specifications

DYNAMIC PERFORMANCE

3 dB Bandwidth

OCM

= 600 mV p-p

210

MHz

Slew Rate

OCM

= 1.5 V to 3.5 V

340

µs

DC PERFORMANCE

Input Voltage Range

1 to 3.7

Input Resistance

130

Input Offset Voltage

OS,cm

= V

OUT,cm

; V

DIN+

= V

DIN

= V

OCM

= 2.5 V

±5

±11

Input Bias Current

0.5

µA

OCM

CMRR

OUT,dm

OCM

];

OCM

= 2.5

± 1 V;

Resistors Matched to 0.01%

Gain

OUT,cm

OCM

;

OCM

= 2.5

± 1 V

0.985

1.015

V/V

POWER SUPPLY

Operating Range

2.7

Quiescent Current

DIN+

= V

DIN

= V

OCM

= 2.5 V

9.4

10.7

MIN

to T

MAX

Variation

µA/°C

Power Supply Rejection Ratio

OUT,dm

;

±1 V

OPERATING TEMPERATURE RANGE

+85

°C

Specifications subject to change without notice.

(@ 25 C, V

= 5 V, V

OCM

= 2.5 V, G = 1, R

L,dm

= 499 , R

= R

= 348

unless otherwise noted. For G = 2,

L,dm

= 200

, R

= 1000

, R

= 499

. Refer to TPC 1 and TPC 10 for test setup and label descriptions. All specifications refer to single-

ended input and differential outputs unless otherwise noted.)

SPECIFICATIONS

REV. B

AD8132SPECIFICATIONS

arameter

Conditions

Min

Typ

Max

Unit

to OUT Specifications

DYNAMIC PERFORMANCE

3 dB Large Signal Bandwidth

OUT

= 1 V p-p

350

MHz

OUT

= 1 V p-p, G = 2

165

MHz

3 dB Small Signal Bandwidth

OUT

= 0.2 V p-p

350

MHz

OUT

= 0.2 V p-p, G = 2

150

MHz

Bandwidth for 0.1 dB Flatness

OUT

= 0.2 V p-p

MHz

OUT

= 0.2 V p-p, G = 2

MHz

NOISE/HARMONIC PERFORMANCE

Second Harmonic

OUT

= 1 V p-p, 1 MHz, R

L,dm

= 800

100

dBc

OUT

= 1 V p-p, 5 MHz, R

L,dm

= 800

dBc

OUT

= 1 V p-p, 20 MHz, R

L,dm

= 800

dBc

Third Harmonic

OUT

= 1 V p-p, 1 MHz, R

L,dm

= 800

dBc

OUT

= 1 V p-p, 5 MHz, R

L,dm

= 800

dBc

OUT

= 1 V p-p, 20 MHz, R

L,dm

= 800

dBc

INPUT CHARACTERISTICS

Offset Voltage (RTI)

OS,dm

= V

OUT,dm

/2; V

DIN+

= V

DIN

= V

OCM

= 1.5 V

±10

Input Bias Current

µA

CMRR

OUT,dm

IN,cm

;

IN,cm

±0.5 V;

Resistors Matched to 0.01%

OCM

to OUT Specifications

DC PERFORMANCE

Input Offset Voltage

OS,cm

= V

OUT,cm

; V

DIN+

= V

DIN

= V

OCM

= 1.5 V

±7

Gain

OUT,cm

OCM

;

OCM

±0.5 V

V/V

POWER SUPPLY

Operating Range

2.7

Quiescent Current

DIN+

= V

DIN

= V

OCM

= 0 V

7.25

Power Supply Rejection Ratio

OUT,dm

;

±0.5 V

OPERATING TEMPERATURE RANGE

+85

°C

Specifications subject to change without notice.

(@ 25 C, V

= 3 V, V

OCM

= 1.5 V, G = 1, R

L,dm

= 499

, R

= R

= 348

unless

otherwise noted. For G = 2, R

L,dm

= 200 , R

= 1000

, R

= 499

. Refer to TPC 1 and TPC 10 for test setup and label descriptions. All

specifications refer to single-ended input and differential outputs unless otherwise noted.)

REV. B

AD8132

ABSOLUTE MAXIMUM RATINGS

1, 2

Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

±5.5 V

OCM

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

±V

Internal Power Dissipation . . . . . . . . . . . . . . . . . . . . 250 mW
Operating Temperature Range . . . . . . . . . . . 40

°C to +85°C

Storage Temperature Range . . . . . . . . . . . . 65

°C to +150°C

Lead Temperature (Soldering 10 sec) . . . . . . . . . . . . . 300

°C

NOTES

Stresses above those listed under Absolute Maximum Ratings may cause perma-

nent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above listed in the operational section of this
specification is not implied. Exposure to Absolute Maximum Ratings for any
extended periods may affect device reliability.

Thermal resistance measured on SEMI standard 4-layer board.

8-Lead SOIC:

= 121

°C/W

8-Lead

µSOIC:

= 142

°C/W

AMBIENT TEMPERATURE C

50

= 150 C

2.0

1.5

1.0

MAXIMUM POWER DISSIPATION

Watts

8-LEAD SOIC

PACKAGE

40 30

40 50

80 90

8-LEAD

microSOIC

0.5

20 10

Figure 2. Plot of Maximum Power Dissipation vs.
Temperature

ORDERING GUIDE

Model

Temperature Range

Package Description

Package Option

Branding Information

AD8132AR

°C to +85°C

8-Lead SOIC

SO-8

AD8132AR-REEL

°C to +85°C

8-Lead SOIC

13" Tape and Reel

AD8132AR-REEL7

°C to +85°C

8-Lead SOIC

7" Tape and Reel

AD8132ARM

°C to +85°C

8-Lead

µSOIC

RM-8

HMA

AD8132ARM-REEL

°C to +85°C

8-Lead

µSOIC

13" Tape and Reel

HMA

AD8132ARM-REEL7

°C to +85°C

8-Lead

µSOIC

7" Tape and Reel

HMA

AD8132-EVAL

Evaluation Board

NOTES

13" Reels of 2500 each.

7" Reels of 1000 each.

13" Reels of 3000 each.

PIN FUNCTION DESCRIPTIONS

Pin No.

Mnemonic Function

Negative Input

OCM

Voltage applied to this pin sets the
common-mode output voltage with a
ratio of 1:1. For example, 1 V dc on
V

OCM

will set the dc bias level on

+OUT and OUT to 1 V.

V+

Positive Supply Voltage

+OUT

Positive Output. Note: the voltage at
D

is inverted at +OUT.

OUT

Negative Output. Note: the voltage at
+D

is inverted at OUT.

Negative Supply Voltage

No Connect

+IN

Positive Input

PIN CONFIGURATION

AD8132

NC = NO CONNECT

IN

+IN

OCM

V+

+OUT

OUT

CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection. Although
the AD8132 features proprietary ESD protection circuitry, permanent damage may occur on
devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions are
recommended to avoid performance degradation or loss of functionality.

WARNING!

ESD SENSITIVE DEVICE

REV. B

AD8132

0.1 F

348

49.9

24.9

348

499

TPC 1. Basic Test Circuit, G = 1

FREQUENCY MHz

GAIN

100

AS SHOWN

G = 1
V

O,dm

= 0.2V p-p

L,dm

= 499

0.2

0.1

0.0

0.1

0.2

0.3

0.4

0.5

= 3V

= 5V

TPC 4. 0.1 dB Flatness vs. Frequency;
C

= 0.5 pF

FREQUENCY MHz

GAIN

100

= 5V

G = 1
V

O,dm

= 2V p-p

L,dm

= 499

TEMPERATURE AS SHOWN

40 C

+85 C

+25 C

TPC 7. Large Signal Response vs.
Temperature

FREQUENCY MHz

GAIN

100

AS SHOWN

G = 1
V

O,dm

= 0.2V p-p

L,dm

= 499

= 3V

= 5V

TPC 2. Small Signal Frequency
Response

FREQUENCY MHz

GAIN

100

AS SHOWN

G = 1
V

O,dm

= 2V p-p FOR V

= 5V, 5V

O,dm

= 1V p-p FOR V

= 3V

L,dm

= 499

= 3V

= 5V

= 3V

TPC 5. Large Signal Frequency
Response; C

= 0 pF

FREQUENCY MHz

GAIN

100

= 5V

G = 1
V

O,dm

= 2V p-p

L,dm

= 499

AS SHOWN

= 499

= 348

= 249

TPC 8. Large Signal Frequency
Response vs. R

FREQUENCY MHz

GAIN

100

0.4

0.3

0.2

0.1

0.0

0.1

0.2

0.3

0.4

0.5

AS SHOWN

G = 1
V

O,dm

= 0.2V p-p

L,dm

= 499

= 3V

= 5V

TPC 3. 0.1 dB Flatness vs. Frequency;
C

= 0 pF

FREQUENCY MHz

GAIN

100

AS SHOWN

G = 1
V

O,dm

= 2V p-p FOR V

= 5V, 5V

O,dm

= 1V p-p FOR V

= 3V

L,dm

= 499

= 3V

= 5V

= 3V

TPC 6. Large Signal Frequency
Response; C

= 0.5 pF

FREQUENCY MHz

IMPEDANCE

100

0.1

100

= 5V

TPC 9. Closed-Loop Single-Ended
Z

OUT

vs. Frequency; G = 1

Typical Performance Characteristics

REV. B

AD8132

FREQUENCY MHz

GAIN

100

AS SHOWN

G = 2
V

O,dm

= 0.2V p-p

L,dm

= 200

= 3V

= 5V,

+5V

TPC 11. Small Signal Frequency
Response

FREQUENCY MHz

GAIN

100

= 5V

G = 2
V

O,dm

= 0.2V p-p

L,dm

= 200

AS SHOWN

= 1.0k

= 499

= 1.5k

TPC 14. Small Signal Frequency
Response vs. R

0.1 F

49.9

24.9

G = 1: R

= R

= 348 , R

= 249 (R

L,dm

= 498 )

G = 2: R

= 1000 , R

= 499 , R

= 100

L,dm

= 200 )

TPC 17. Test Circuit for Output
Balance

FREQUENCY MHz

GAIN

100

= 3V, 5V, 5V

G = 2
V

O,dm

= 0.2V p-p

L,dm

= 200

6.1

6.0

5.9

5.8

5.7

5.6

5.5

TPC 12. 0.1 dB Flatness vs.
Frequency

0.1 F

499

49.9

24.9

200

TPC 15. Test Circuit for Various
Gains

FREQUENCY MHz

RTI BALANCE ERROR

100

25

30

35

40

45

50

55

= 5V

GAIN AS SHOWN

OUT,dm

= 2V p-p

OUT,cm

/ V

OUT,dm

60

65

G = 1

G = 2

70

75

TPC 18. RTI Output Balance
Error vs. Frequency

0.1 F

499

49.9

24.9

1000

200

TPC 10. Basic Test Circuit, G = 2

FREQUENCY MHz

GAIN

100

= 5V, 5V

= 3V

AS SHOWN

G = 2
V

O,dm

= 2V p-p FOR

= 5V, 5V

O,dm

= 1V p-p FOR

= 3V

L,dm

= 200

TPC 13. Large Signal Frequency
Response

FREQUENCY MHz

GAIN

100

= 5V

O, dm

= 2V p-p

L, dm

= 200

= 499

10

15

G = 10, R

= 4.99k

G = 5, R

= 2.49k

G = 2, R

= 1k

G = 1, R

= 499

TPC 16. Large Signal Response for
Various Gains

REV. B

AD8132

0.1 F

348

49.9

24.9

348

LPF

300

HPF

= 50

2:1 TRANSFORMER

TPC 19. Harmonic Distortion Test Circuit,
G = 1, R

L,dm

= 800

FREQUENCY MHz

DISTORTION

dBc

40

50

60

70

80

90

100

110

L,dm

= 800

OUT,dm

= 1V p-p

HD3 (V

= 3V)

HD2 (V

= 3V)

HD2 (V

= 5V)

HD3 (V

= 5V)

TPC 20. Harmonic Distortion vs.
Frequency, G = 1

DIFFERENTIAL OUTPUT VOLTAGE V p-p

DISTORTION

dBc

40

50

60

70

80

90

100

110

= 5V

L,dm

= 800

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 23. Harmonic Distortion vs.
Differential Output Voltage, G = 1

FREQUENCY MHz

DISTORTION

dBc

40

50

60

70

80

90

100

110

L,dm

= 800

OUT,dm

= 2V p-p

HD3 (V

= 5V)

HD2 (V

= 5V)

HD2 (V

= 5V)

HD3 (V

= 5V)

30

TPC 21. Harmonic Distortion vs.
Frequency, G = 1

DIFFERENTIAL OUTPUT VOLTAGE V p-p

DISTORTION

dBc

40

50

60

70

80

90

100

110

= 5V

L,dm

= 800

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 24. Harmonic Distortion vs.
Differential Output Voltage, G = 1

DIFFERENTIAL OUTPUT VOLTAGE V p-p

DISTORTION

dBc

0.25

1.50

1.75

40

50

60

70

80

90

100

0.75

1.00

1.25

0.50

110

= 3V

L,dm

= 800

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 22. Harmonic Distortion vs.
Differential Output Voltage, G = 1

LOAD

DISTORTION

dBc

200

700

800

50

60

70

80

90

100

400

500

600

300

110

= 3V

O,dm

= 1V p-p

900 1000

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 25. Harmonic Distortion vs.
R

LOAD

, G = 1

REV. B

AD8132

LOAD

DISTORTION

dBc

200

700

800

50

60

70

80

90

100

400

500

600

300

110

= 5V

OUT,dm

= 2V p-p

900 1000

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 26. Harmonic Distortion vs.
R

LOAD

, G = 1

LOAD

DISTORTION

dBc

200

700

800

50

60

70

80

90

100

400

500

600

300

110

= 5V

OUT,dm

= 2V p-p

HD3 (F = 20MHz)

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

900 1000

TPC 27. Harmonic Distortion vs.
R

LOAD

, G = 1

0.1 F

499

49.9

24.9

1000

LPF

300

HPF

= 50

2:1 TRANSFORMER

TPC 28. Harmonic Distortion Test Circuit, G = 2, R

L,dm

= 800

FREQUENCY MHz

DISTORTION

dBc

50

60

70

80

90

100

110

HD3 (V

= 3V)

L,dm

= 800

OUT,dm

= 1V p-p

40

HD3 (V

= 5V)

HD2 (V

= 5V)

HD2 (V

= 3V)

TPC 29. Harmonic Distortion vs.
Frequency, G = 2

FREQUENCY MHz

DISTORTION

dBc

50

60

70

80

90

100

HD3 (V

= 5V)

L,dm

= 800

OUT,dm

= 4V p-p

40

HD3 (V

= 5V)

HD2 (V

= 5V)

30

20

HD2 (V

= 5V)

TPC 30. Harmonic Distortion vs.
Frequency, G = 2

DIFFERENTIAL OUTPUT VOLTAGE V p-p

DISTORTION

dBc

50

60

70

80

90

100

= 5V

L,dm

= 800

40

HD3 (F = 20MHz)

110

120

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 31. Harmonic Distortion vs.
Differential Output Voltage, G = 2

REV. B

AD8132

DIFFERENTIAL OUTPUT VOLTAGE V p-p

DISTORTION

dBc

50

60

70

80

90

100

= 5V

L,dm

= 800

40

HD3 (F = 20MHz)

110

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

TPC 32. Harmonic Distortion vs.
Differential Output Voltage, G = 2

FREQUENCY MHz

OUT

dBm (Re:50

)

19.5

10

20

30

40

50

60

70

80

90

20.5

= 20MHz

= 5V

L,dm

= 800

TPC 35. Intermodulation
Distortion, G = 1

300mV

5ns

= 3V

OUT,dm

= 1.5V p-p

= 0pF

= 0.5pF

TPC 38. Large Signal Transient
Response, G = 1

LOAD

DISTORTION

dBc

400

50

60

70

80

90

100

300

200

500

HD3 (F = 20MHz)

600

110

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

700

800

= 5V

OUT,dm

= 2V p-p

900 1000

TPC 33. Harmonic Distortion vs.
R

LOAD

, G = 2

FREQUENCY MHz

INTERCEPT

dBm (Re:50

)

= 5V, 5V

L,dm

= 800

TPC 36. Third Order Intercept vs.
Frequency, G = 1

400mV

5ns

= 5V

OUT,dm

= 2V p-p

= 0pF

= 0.5pF

TPC 39. Large Signal Transient
Response, G = 1

LOAD

DISTORTION

dBc

400

50

60

70

80

90

100

300

200

500

HD3 (F = 20MHz)

600

110

HD2 (F = 20MHz)

HD2 (F = 5MHz)

HD3 (F = 5MHz)

700

800

= 5V

OUT,dm

= 2V p-p

900 1000

TPC 34. Harmonic Distortion vs.
R

LOAD

, G = 2

= 5V, 5V, 3V

40mV

5ns

TPC 37. Small Signal Transient
Response, G = 1

= 5V

OUT,dm

= 2V p-p

400mV

5ns

= 0pF

= 0.5pF

TPC 40. Large Signal Transient
Response, G = 1

REV. B

AD8132

348

49.9

348

249

OUT,dm

OUT, cm

NOTE: RESISTORS MATCHED TO 0.01%.

TPC 50. CMRR Test Circuit

= 5V

OCM

= 1V TO +1V

400mV

5ns

OUT,cm

TPC 53. V

OCM

Transient Response

FREQUENCY Hz

1000

100

10k

100k

10M 100M

1.8pA/ Hz

INPUT CURRENT NOISE

pA/ Hz

TPC 56. Input Current Noise vs.
Frequency

FREQUENCY MHz

CMRR

100

1000

70

80

50

60

30

40

20

OUT,dm

IN,cm

OUT,cm

IN,cm

= 5V

IN,cm

= 2V p-p

TPC 51. CMRR vs. Frequency

FREQUENCY MHz

OCM

CMRR

100

1000

70

80

50

60

30

40

20

OCM

= 2V p-p

OCM

= 600mV p-p

OUT,dm

OCM

10

TPC 54. V

OCM

CMRR vs. Frequency

5ns

OUT,dm

(0.5V/DIV)

IN,sm

(1V/DIV)

= 5V

= 2.5V STEP

G = 2
R

= 1k

L,dm

= 200

V/DIV AS SHOWN

TPC 57. Overdrive Recovery

FREQUENCY MHz

100

1000

12

OUT,cm

OCM

= 600mV p-p

OCM

= 2V p-p

15

= 5V

TPC 52. V

OCM

Gain Response

FREQUENCY Hz

INPUT VOLTAGE NOISE

nV/ Hz

1000

100

10k

100k

10M

8nV/ Hz

100M

TPC 55. Input Voltage Noise vs.
Frequency

TEMPERATURE C

SUPPLY CURRENT

50

30

10

= 5V

TPC 58. Quiescent Current vs.
Temperature

REV. B

AD8132

OPERATIONAL DESCRIPTION
Definition of Terms

AD8132

+IN

IN

OCM

L, dm

+OUT

OUT, dm

OUT

Figure 3. Circuit Definitions

Differential voltage refers to the difference between two node
voltages. For example, the output differential voltage (or
equivalently output differential-mode voltage) is defined as:

OUT dm

OUT

(

)

+OUT

and V

OUT

refer to the voltages at the +OUT and OUT

terminals with respect to a common reference.

Common-mode voltage refers to the average of two node volt-
ages. The output common-mode voltage is defined as:

OUT cm

OUT

(

)

Basic Circuit Operation

One of the more useful and easy to understand ways to use the
AD8132 is to provide two equal-ratio feedback networks. To match
the effect of parasitics, these networks should actually be comprised
of two equal-value feedback resistors, R

and two equal-value gain

resistors, R

. This circuit is diagrammed in Figure 3.

Like a conventional op amp, the AD8132 has two differential
inputs that can be driven with both a differential-mode input
voltage, V

IN,dm

, and a common-mode input voltage, V

IN,cm

There is another input, V

OCM

, which is not present on conven-

tional op amps, but provides another input to consider on the
AD8132. It is totally separate from the above inputs.

There are two complementary outputs whose response can be
defined by a differential-mode output, V

OUT,dm

and a common-

mode output, V

OUT,cm

TEMPERATURE C

DIFFERENTIAL OUTPUT OFFSET

0.5

2.5

40

20

100

1.0

1.5

2.0

= 5V

TPC 59. Differential Offset Voltage vs. Temperature

Table I indicates the gain from any type of input to either type
of output.

Table I. Differential and Common-Mode Gains

Input

OUT,dm

OUT,cm

IN,dm

0 (By Design)

IN,cm

0 (By Design)

OCM

1 (By Design)

The differential output (V

OUT,dm

) is equal to the differential

input voltage (V

IN,dm

) times R

. In this case, it does not

matter if both differential inputs are driven, or only one output
is driven and the other is tied to a reference voltage, like ground.
As can be seen from the two zero entries in the first column,
neither of the common-mode inputs has any effect on this gain.

The gain from V

IN,dm

to V

OUT,cm

is 0 and to first order does not

depend on the ratio matching of the feedback networks. The
common-mode feedback loop within the AD8132 provides a
corrective action to keep this gain term minimized. The term
"balance error" describes the degree to which this gain term
differs from zero.

The gain from V

IN,cm

to V

OUT,dm

does directly depend on the

matching of the feedback networks. The analogous term for this
transfer function, which is used in conventional op amps, is
"common-mode rejection ratio" or CMRR. Thus, if it is desirable
to have a high CMRR, the feedback ratios must be well matched.

The gain from V

IN,cm

to V

OUT,cm

is also ideally 0, and is first-

order independent of the feedback ratio matching. As in the
case of V

IN,dm

to V

OUT,cm

, the common-mode feedback loop

keeps this term minimized.

The gain from V

OCM

to V

OUT,dm

is ideally 0 only when the feed-

back ratios are matched. The amount of differential output
signal that will be created by varying V

OCM

is related to the

degree of mismatch in the feedback networks.

OCM

controls the output common-mode voltage V

OUT,cm

with a

unity-gain transfer function. With equal-ratio feedback networks
(as assumed above), its effect on each output will be the same,
which is another way to say that the gain from V

OCM

to V

OUT,dm

is zero. If not driven, the output common-mode will be at mid-
supplies. It is recommended that a 0.1

µF bypass capacitor be

connected to V

OCM

REV. B

AD8132

When unequal feedback ratios are used, the two gains associated
with V

OUT,dm

become nonzero. This significantly complicates

the mathematical analysis along with any intuitive understand-
ing of how the part operates. Some of these configurations will
be in another section.

THEORY OF OPERATION

The AD8132 differs from conventional op amps by the external
presence of an additional input and output. The additional
input, V

OCM

, controls the output common-mode voltage. The

additional output is the analog complement of the single output
of a conventional op amp. For its operation, the AD8132 makes
use of two feedback loops as compared to the single loop of
conventional op amps. While this provides significant freedom
to create various novel circuits, basic op amp theory can still be
used to analyze the operation.

One of the feedback loops controls the output common-mode
voltage, V

OUT,cm

. Its input is V

OCM

(Pin 2) and the output is the

common-mode, or average voltage, of the two differential outputs
(+OUT and OUT). The gain of this circuit is internally set to
unity. When the AD8132 is operating in its linear region, this
establishes one of the operational constraints: V

OUT,cm

= V

OCM

The second feedback loop controls the differential operation.
Similar to an op amp, the gain and gain-shaping of the transfer
function is controllable by adding passive feedback networks. How-
ever, only one feedback network is required to "close the loop" and
fully constrain the operation. But depending on the function
desired, two feedback networks can be used. This is possible as
a result of having two outputs that are each inverted with respect
to the differential inputs.

General Usage of the AD8132

Several assumptions are made here for a first-order analysis, which
are the typical assumptions used for the analysis of op amps:

· The input impedances are arbitrarily large and their loading

effect can be ignored.

· The input bias currents are sufficiently small so they can be

neglected.

· The output impedances are arbitrarily low.

· The open-loop gain is arbitrarily large, which drives the

amplifier to a state where the input differential voltage is
effectively zero.

· Offset voltages are assumed to be zero.

While it is possible to operate the AD8132 with a purely differ-
ential input, many of its applications call for a circuit that has a
single-ended input with a differential output.

For a single-ended-to-differential circuit, the R

of the undriven

input will be tied to a reference voltage. For now this is ground,
and other conditions will be discussed later. Also, the voltage at
V

OCM

, and hence V

OUT,cm

will be assumed to be ground for now.

Figure 4 shows a generalized schematic of such a circuit using
an AD8132 with two feedback paths.

For each feedback network, a feedback factor can be defined,
which is the fraction of the output signal that is fed back to the
opposite-sign input. These terms are:

(

)

(

)

The feedback factor

1 is for the side that is driven, while the

feedback factor

2 is for the side that is tied to a reference volt-

age, (ground for now). Note also that each feedback factor can
vary anywhere between 0 and 1.

A single-ended-to-differential gain equation can be derived
which is true for all values of

1 and 2:

= × -

(

)

(

)

This expression is not very intuitive, but some further examples
can provide better understanding of its implications. One obser-
vation that can be made right away is that a tolerance error in

does not have the same effect on gain as the same tolerance
error in

Resistorless Differential Amplifier (High Input Impedance
Inverting Amplifier)

The simplest closed-loop circuit that can be made does not require
any resistors and is shown in Figure 7. In this circuit,

1 is equal

to zero, and

2 is equal to one. The gain is equal to two.

A more intuitive means to figure the gain is by simple inspec-
tion. +OUT is connected to IN, whose voltage is equal to the
voltage at +IN under equilibrium conditions. Thus, +V

OUT

equal to V

, and there is unity gain in this path. Since OUT

has to swing in the opposite direction from +OUT due to the
common-mode constraint, its effect will double the output
signal and produce a gain of two.

One useful function that this circuit provides is a high input-
impedance inverter. If +OUT is ignored, there is a unity-gain,
high-input-impedance amplifier formed from +IN to OUT.
Most traditional op amp inverters have relatively low input
impedances, unless they are buffered with another amplifier.

OCM

has been assumed to be at midsupply. Since there is

still the constraint from the above discussion that +V

OUT

must

equal V

, changing the V

OCM

voltage will not change +V

OUT

(= V

). Therefore, all of the effect of changing V

OCM

must

show up at OUT.

For example, if V

OCM

is raised by 1 V, then V

OUT

must go up

by 2 V. This makes V

OUT,cm

also go up by 1 V, since it is defined

as the average of the two differential output voltages. This means
that the gain from V

OCM

to the differential output is two.

Other 2 = 1 Circuits

The above simple configuration with

2 = 1 and its gain-of-two

is the highest gain circuit that can be made under this condition.
Since

1 was equal to zero, only higher 1 values are possible.

All of these circuits with higher values of

1 will have gains lower

than two. However, circuits with

1 equal to one are not practical,

because they have no effective input, and result in a gain of 0.

To increase

1 from zero, it is necessary to add two resistors in

a feedback network. A generalized circuit that has

1 with a

value higher than zero is shown in Figure 6. A couple of differ-
ent convenient gains that can be created are a gain of 1, when
1 is equal to 1/3, and a gain of 0.5 when 1 equals 0.6.
In all of these circuits with

2 equal to 1, V

OCM

serves as the

reference voltage from which to measure the input voltage and
the individual output voltages. In general, when V

OCM

is varied

in these circuits, a differential output signal will be generated in
addition to V

OUT,cm

changing the same amount as the voltage

change of V

OCM

REV. B

AD8132

Varying 2

While the circuit above sets

2 to 1, another class of simple

circuits can be made that set

2 equal to zero. This means that

there is no feedback from +OUT to IN. This class of circuits is
very similar to a conventional inverting op amp. However, the
AD8132 circuits have an additional output and common-mode
input which can be analyzed separately (see Figure 8).

With IN connected to ground, +IN becomes a "virtual ground"
in the same sense that the term is used in conventional op amps.
Both inputs must maintain the same voltage for equilibrium
operation, so if one is set to ground, the other will be driven to
ground. The input impedance can also be seen to be equal to
R

, just as in a conventional op amp.

In this case, however, the positive input and negative output are
used for the feedback network. Since a conventional op amp does
not have a negative output, only its inverting input can be used for
the feedback network. The AD8132 is symmetrical, so the feedback
network on either side can be used to produce the same results.

Since +IN is a summing junction, by analogy to conventional op
amps, the gain from V

to OUT will be R

. This will hold

true regardless of the voltage on V

OCM

. And since +OUT will

move the same amount in the opposite direction from OUT,
the overall gain will be 2 (R

OCM

still governs V

OUT,cm

, so +OUT must be the only output

that moves when V

OCM

is varied. Since V

OUT,cm

is the average of

the two outputs, +OUT must move twice as fast and in the
same direction as V

OCM

to create the proper V

OUT,cm

. Therefore,

the gain from V

OCM

to +OUT must be two.

In these circuits with

2 equal to zero, the gain can theoretically

be set to any value from close to zero to infinity, just as it can
with a conventional op amp in the inverting mode. However,
practical real-world limitations and parasitics will limit the range
of acceptable gains to more modest values.

1 = 0

There is yet another class of circuits where there is no feedback
from OUT to +IN. This is the case where

1 = 0. The resistorless

differential amplifier described above meets this condition, but
it was presented only with the condition that

2 = 1. Recall that

this circuit had a gain equal to two.

2 is decreased in this circuit from unity, a smaller part of

OUT

will be fed back to IN and the gain will increase. See

Figure 5. This circuit is very similar to a noninverting op amp
configuration, except for the presence of the additional comple-
mentary output. Therefore, the overall gain is twice that of a
noninverting op amp or 2

× (1 + R

) or 2

× (1/ 2).

Once again, varying V

OCM

will not affect both outputs in the

same way, so in addition to varying V

OUT,cm

with unity gain,

there will also be an affect on V

OUT,dm

by changing V

OCM

Estimating the Output Noise Voltage

Similar to the case of a conventional op amp, the differential
output errors (noise and offset voltages) can be estimated by
multiplying the input referred terms, at +IN and IN, by the
circuit noise gain. The noise gain is defined as:

= +

To compute the total output referred noise for the circuit of
Figure 3, consideration must also be given to the contribution of
the resistors R

and R

. Refer to Table II for estimated output

noise voltage densities at various closed-loop gains.

Table II. Recommended Resistor Values and
Noise Performance for Specific Gains

Bandwidth Output Noise Output Noise

Gain

( ) ( )

3 dB

AD8132 Only AD8132 + R

, R

499 499

360 MHz

16 nV/

17 nV/

499 1.0 k

160 MHz

24.1 nV/

Hz 26.1 nV/Hz

499 2.49 k 65 MHz

48.4 nV/

Hz 53.3 nV/Hz

499 4.99 k 20 MHz

88.9 nV/

Hz 98.6 nV/Hz

Calculating an Application Circuit's Input Impedance

The effective input impedance of a circuit such as that in Fig-
ure 3, at +D

and D

, will depend on whether the amplifier is

being driven by a single-ended or differential signal source. For
balanced differential input signals, the input impedance (R

,dm)

between the inputs (+D

and D

) is simply:

IN dm

= ×

In the case of a single-ended input signal (for example if D

grounded and the input signal is applied to +D

), the input

impedance becomes:

IN dm

(

)

The circuit's input impedance is effectively higher than it would
be for a conventional op amp connected as an inverter because a
fraction of the differential output voltage appears at the inputs
as a common-mode signal, partially bootstrapping the voltage
across the input resistor R

Input Common-Mode Voltage Range in Single Supply
Applications

The AD8132 is optimized for level-shifting "ground" referenced
input signals. For a single-ended input this would imply, for
example, that the voltage at D

in Figure 3 would be zero

volts when the amplifier's negative power supply voltage (at V)
was also set to zero volts.

Setting the Output Common-Mode Voltage

The AD8132's V

OCM

pin is internally biased at a voltage approxi-

mately equal to the midsupply point (average value of the voltages
on V+ and V). Relying on this internal bias will result in an
output common-mode voltage that is within about 100 mV of
the expected value.

In cases where more accurate control of the output common-mode
level is required, it is recommended that an external source,
or resistor divider (with R

SOURCE

< 10K), be used. The output

common-mode offset specified on pages 2 and 3 assume the
V

OCM

input is driven by a low impedance voltage source.

REV. B

AD8132

Driving a Capacitive Load

A purely capacitive load can react with the pin and bondwire
inductance of the AD8132 resulting in high frequency ringing in
the pulse response. One way to minimize this effect is to place a
small capacitor across each of the feedback resistors. The added
capacitance should be small to avoid destabilizing the amplifier.
An alternative technique is to place a small resistor in series with
the amplifier's outputs as shown in TPC 47.

LAYOUT, GROUNDING AND BYPASSING

As a high-speed part, the AD8132 is sensitive to the PCB
environment in which it has to operate. Realizing its superior
specifications requires attention to various details of good high-
speed PCB design.

The first requirement is a good solid ground plane that covers as
much of the board area around the AD8132 as possible. The
only exception to this is that the two input pins (Pins 1 and 8)
should be kept a few mm from the ground plane, and ground
should be removed from inner layers and the opposite side of
the board under the input pins. This will minimize the stray
capacitance on these nodes and help preserve the gain flatness
vs. frequency.

The power supply pins should be bypassed as close as possible
to the device to the nearby ground plane. Good high-frequency
ceramic chip capacitors should be used. This bypassing should
be done with a capacitance value of 0.01

µF to 0.1 µF for each

supply. Further away, low frequency bypassing should be provided
with 10

µF tantalum capacitors from each supply to ground.

The signal routing should be short and direct in order to avoid
parasitic effects. Wherever there are complementary signals, a
symmetrical layout should be provided to the extent possible to
maximize the balance performance. When running differential
signals over a long distance, the traces on PCB should be close
together or any differential wiring should be twisted together to
minimize the area of the loop that is formed. This will reduce
the radiated energy and make the circuit less susceptible to
interference.

CIRCUITS

Figure 4. Typical Four-Resistor Feedback Circuit

Figure 5. Typical Circuit with

1 = 0

Figure 6. Typical Circuit with

2 = 1

Figure 7. Resistorless G = 2 Circuit with

1 = 0

Figure 8. Typical Circuit with

2 = 0

REV. B

AD8132

10

20

30

40

50

60

70

80

90

100

110

120

2.5

5.0

7.5

10.0

12.5

15.0

17.5

20.0

FUND

2ND

3RD

4TH

5TH

7TH

8TH

9TH

6TH

= 40MHz

= 2.5MHz

INPUT FREQUENCY MHz

OUTPUT

dBc

Figure 10. FFT Response for AD8132 Driving AD9203

Balanced Cable Driver

When driving a twisted pair cable, it is desirable to drive only a
pure differential signal onto the line. If the signal is purely dif-
ferential (i.e., fully balanced), and the transmission line is twisted
and balanced, there will be a minimum radiation of any signal.

0.1 F

10 F

348

0.1 F

348

49.9

348

24.9

10k

1V p-p

348

60.4

20pF

AINN

AINP

AVDD

DRVDD

AVSS

DRVSS

AD9203

DIGITAL
OUTPUTS

0.1 F

AD8132

Figure 9. AD8132 Driving AD9203, a 10-Bit 40 MSPS A/D Converter

APPLICATIONS
A/D Driver

Many of the newer high-speed A/D converters are single-supply
and have differential inputs. Thus, the driver for these devices
should be able to convert from a single-ended to a differential
signal and provide output common-mode level-shifting in
addition to having low distortion and noise. The AD8132 con-
veniently performs these functions when driving the AD9203, a
10-bit, 40 MSPS A/D converter.

In Figure 9 a 1 V p-p signal drives the input of an AD8132 configured
for unity gain. Both the AD8132 and the AD9203 are powered
from a single 3 V supply. A voltage divider biases V

OCM

at midsupply,

which in turn drives V

OUT,cm

to be half the supply voltage. This is

within the common-mode range of the AD9203.

Between the A/D and the driver is a one-pole, differential filter
that helps to filter some of the noise and assists the switched-
capacitor inputs of the A/D. Each of the A/D inputs will be driven
by a 0.5 V p-p signal that goes from 1.25 V dc to 1.75 V dc.

Figure 10 is an FFT plot of the performance of the circuit when run-
ning at a clock rate of 40 MSPS and an input frequency of 2.5 MHz.

499

523

10 F

+5V

AD8132

0.1 F

49.9

SOURCE

0.1 F

10 F

5V

49.9

TWISTED

PAIR

100

AD830

0.1 F

10 F

5V

10 F

+5V

0.1 F

OUT

Figure 11. Balanced Line Driver and Receiver Using AD8132 and AD830

REV. B

AD8132

Low-Pass Differential Filter

Similar to an op amp, various types of active filters can be cre-
ated with the AD8132. These can have single-ended inputs and
differential outputs, which can provide an antialias function
when driving a differential A/D converter.

Figure 14 is a schematic of a low-pass, multiple-feedback filter.
The active section contains two poles, and an additional pole is
added at the output. The filter was designed to have a 3 dB
frequency of 1 MHz. The actual 3 dB frequency was measured
to be 1.12 MHz as shown in Figure 15.

33pF

2.15k

953

33pF

2.15k

100pF
100pF

24.9

49.9

549

200pF

OUT

Figure 14. 1 MHz, 3-Pole Differential Output Low-Pass
Multiple Feedback Filter

FREQUENCY Hz

10k

10

20

30

40

50

60

70

80

90

100k

10M

100M

OUT

Figure 15. Frequency Response of 1 MHz Low-Pass Filter

High Common-Mode Output Impedance Amplifier

Changing the connection to V

OCM

(Pin 2) can change the

common-mode from low impedance to high impedance. If
V

OCM

is actively set to a particular voltage, the AD8132 will try

to force V

OUT,cm

to the same voltage with a relatively low output

impedance. All the previous analysis assumed that this output
impedance is arbitrarily low enough to drive the load condition
in the circuit.

However, the are some applications that benefit from a high
common-mode output impedance. This can be accomplished
with the circuit shown in Figure 16.

348

49.9

Figure 16. High Common-Mode Output Impedance Differ-
ential Amplifier

The complementary electrical fields will mostly be confined to
the space between the two twisted conductors and will not sig-
nificantly radiate out from the cable. The current in the cable will
create magnetic fields that will radiate to some degree. However,
the amount of radiation is mitigated by the twists, because for
each twist, the two adjacent twists will have an opposite polarity
magnetic field. If the twist pitch is tight enough, these small
magnetic field loops will contain most of the magnetic flux,
and the magnetic far-field strength will be negligible.

Any imbalance in the differential drive signal will appear as a
common-mode signal on the cable. This is the equivalent of a
single wire that is driven with the common-mode signal. In this
case, the wire will act as an antenna and radiate. Thus, in order
to minimize radiation when driving differential twisted pair
cables, the differential drive signal should be very well balanced.

The common-mode feedback loop in the AD8132 helps to
minimize the amount of common-mode voltage at the output,
and can therefore be used to create a well-balanced differential
line driver. Figure 11 shows an application that uses an AD8132
as a balanced line driver and AD830 as a differential receiver
configured for unity gain. This circuit was operated with 10 m
of Category 5 cable.

Transmit Equalizer

Any length of transmission line will attenuate the signals it carries.
This effect is worse at higher frequencies than at low frequen-
cies. One way to compensate for this is to provide an equalizer
circuit that boosts the higher frequencies in the transmitter
circuit, so that at the receive end of the cable, the attenuation
effects are diminished.

By lowering the impedance of the R

component of the feed-

back network at higher frequency, the gain can be increased at
high frequency. Figure 12 shows a gain of a two line driver that
has its R

s shunted by 10 pF capacitors. The effect of this is shown

in the frequency response plot of Figure 13.

249

49.9

10pF

499

10pF

249

24.9

49.9

499

49.9

100

OUT

Figure 12. Frequency Boost Circuit

1000

10

20

30

40

50

60

70

80

OUT

100

FREQUENCY MHz

Figure 13. Frequency Response for Transmit Boost Circuit

REV. B

AD8132

OCM

is driven by a resistor divider that "measures" the output

common- mode voltage. Thus, the common-mode output volt-
age takes on the value that is set by the driven circuit. In this
case it comes from the center point of the termination at the
receive end of a 10 m length of Category 5 twisted pair cable.

If the receive end common-mode voltage is set to "ground," it
will be well-defined at the receive end. Any common-mode
signal that is picked up over the cable length due to noise, will
appear at the transmit end, and must be "absorbed" by the
transmitter. Thus, it is important that the transmitter have
adequate common-mode output range to absorb the full ampli-
tude of the common-mode signal coupled onto the cable and
thus prevent clipping.

Another way to look at this is that the circuit performs what is
sometimes called "transformer action." One main difference is
that the AD8132 passes dc while transformers do not.

A transformer can also be easily configured to have either a high
or low common-mode output impedance. If the transformer's
center tap is connected to a solid voltage reference, it will set the
common-mode voltage on the secondary side of the transformer.
In this case, if one of the differential outputs is grounded, the
other output will have only half of the differential output signal.
This keeps the common-mode voltage at ground, where it is
required to be due to the center tap connection. This is analo-
gous to the AD8132 operating with a low output impedance
common-mode. See Figure 17.

DIFF

OCM

Figure 17. Transformer Whose Low Output Impedance
Secondary Is Set at V

OCM

If the center tap of the secondary of a transformer is allowed to
float (or there is no center tap), the transformer will have a high
common-mode output impedance. This means that the common-
mode of the secondary will be determined by what it is connected
to, and not by anything to do with the transformer itself.

If one of the differential ends of the transformer is grounded, the
other end will swing with the full output voltage. This means
that the common-mode of the output voltage is one-half of the
differential output voltage. But this shows that the common-mode
is not forced via a low impedance to a given voltage. The common-
mode output voltage can easily be changed to any voltage through
its other output terminals.

The AD8132 can exhibit the same performance when one of the
outputs in Figure 16 is grounded. The other output will swing
at the full differential output voltage. The common-mode signal
is "measured" by the voltage divider across the outputs and input
to V

OCM

. This then drives V

OUT,cm

to the same level. At higher

frequencies, it is important to minimize the capacitance on the
V

OCM

node or else phase shifts can compromise the performance.

The voltage divider resistances can also be lowered for better
frequency response.

DIFF

OCM

Figure 18. Transformer with High Output Impedance
Secondary

Full-Wave Rectifier

The balanced outputs of the AD8132, along with a couple of
Schottky diodes, can create a very high-speed full-wave rectifier.
Such circuits are useful for measuring ac voltages and other
computational tasks.

Figure 19 shows the configuration of such a circuit. Each of the
AD8132 outputs drives the anode of an HP2835 Schottky diode.
These Schottky diodes were chosen for their high-speed opera-
tion. At lower frequencies (approximately lower than 10 MHz),
a silicon signal diode, like a 1N4148 can be used. The cathodes
of the two diodes are connected together and this output node is
connected to ground by a 50

resistor.

348

+5V

5V

100

24.9

49.9

HP2835

OUT

CR1

10k

Figure 19. Full-Wave Rectifier

The diodes should be operated such that they are slightly forward-
biased when the differential output voltage is zero. For the
Schottky diodes, this is about 400 mV. The forward biasing can
be conveniently adjusted by CR1, which, in this circuit, raises
and lowers V

OUT,CM

without creating a differential output voltage.

One advantage of this circuit is that the feedback loop is never
momentarily opened while the diodes reverse their polarity within
the loop. This is the scheme that is sometimes used for full-wave
rectifiers that use conventional op amps. These conventional
circuits do not work well at frequencies above about 1 MHz.

If there is not enough forward bias (V

OUT,cm

too low), the lower

sharp cusps of the full-wave rectified output waveform will be
rounded off. Also, as the frequency increases, there tends to be
some rounding of the lower cusps. The forward bias can be
increased to yield sharper cusps at higher frequencies.

There is not a reliable, entirely quantifiable, means to measure
the performance of a full-wave rectifier. Since the ideal wave-
form has periodic sharp discontinuities, it should have (mostly
even) harmonics that have no upper bound on the frequency.
However, for a practical circuit, as the frequency increases, the
higher harmonics become attenuated and the sharp cusps that
are present at low frequencies become significantly rounded.

REV. B

C0103501/02(B)

PRINTED IN U.S.A.

AD8132

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

8-Lead SOIC

(R-8)

0.0098 (0.25)
0.0075 (0.19)

0.0500 (1.27)
0.0160 (0.41)

8
0

0.0196 (0.50)
0.0099 (0.25)

0.1968 (5.00)
0.1890 (4.80)

0.2440 (6.20)
0.2284 (5.80)

PIN 1

0.1574 (4.00)
0.1497 (3.80)

0.0500 (1.27)

BSC

0.0688 (1.75)
0.0532 (1.35)

SEATING

PLANE

0.0098 (0.25)
0.0040 (0.10)

0.0192 (0.49)
0.0138 (0.35)

CONTROLLING DIMENSIONS ARE IN MILLIMETERS, INCH DIMENSIONS
ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR REFERENCE
ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

8-Lead microSOIC

(RM-8)

0.011 (0.28)
0.003 (0.08)

0.028 (0.71)
0.016 (0.41)

33
27

0.120 (3.05)
0.112 (2.84)

0.122 (3.10)
0.114 (2.90)

0.199 (5.05)
0.187 (4.75)

PIN 1

0.0256 (0.65) BSC

0.122 (3.10)
0.114 (2.90)

SEATING

PLANE

0.006 (0.15)
0.002 (0.05)

0.018 (0.46)
0.008 (0.20)

0.043 (1.09)
0.037 (0.94)

0.120 (3.05)
0.112 (2.84)

CONTROLLING DIMENSIONS ARE IN MILLIMETERS, INCH DIMENSIONS
ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR REFERENCE
ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

The circuit was run at a frequency up to 300 MHz and, while
it was still functional, the major harmonic that remained in
the output was the second. This made it look like a sine
wave at 600 MHz. Figure 20 is an oscilloscope plot of the
output when driven by a 100 MHz, 2.5 V p-p input.

Sometimes a second harmonic generator is actually useful, as
for creating a clock to oversample a DAC by a factor of two.
If the output of this circuit is run through a low-pass filter, it
can be used as a second harmonic generator.

Revision History

Location

Page

Data Sheet changed from REV. A to REV. B.

Edits to TRANSMITTER EQUALIZER section . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18

100mV

2ns

Figure 20. Full-Wave Rectifier Response with
100 MHz Input

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