ANALOG DEVICES AD 8012 ARZ Datasheet

Dual 350 MHz

8

7

6

5

1

2

3

4

OUT1

–IN1

+IN1

+V

S

OUT2

–IN2

+IN2–V

S

AD8012

Low Power Amplifier

FEATURES
Low Power

1.7 mA/Amplifier Supply Current

Fully Specified for 5 V and +5 V Supplies
High Output Current, 125 mA
High Speed

350 MHz, –3 dB Bandwidth (G = +1)

150 MHz, –3 dB Bandwidth (G = +2)

2,250 V/s Slew Rate

20 ns Settling Time to 0.1%
Low Distortion

–72 dBc Worst Harmonic @ 500 kHz, R

–66 dBc Worst Harmonic @ 5 MHz, R
Good Video Specifications (R

= 1 k, G = +2)

L

= 100 

L

= 1 k

L

0.02% Differential Gain Error

0.06 Differential Phase Error

Gain Flatness 0.1 dB to 40 MHz

60 ns Overdrive Recovery
Low Offset Voltage, 1.5 mV
Low Voltage Noise, 2.5 nV/√Hz
Available in 8-Lead SOIC and 8-Lead MSOP

APPLICATIONS
XDSL, HDSL Line Drivers
ADC Buffers
Professional Cameras
CCD Imaging Systems
Ultrasound Equipment
Digital Cameras

PRODUCT DESCRIPTION

The AD8012 is a dual, low power, current feedback amplifier
capable of providing 350 MHz bandwidth while using only

1.7 mA per amplifier. It is intended for use in high frequency,
wide dynamic range systems where low distortion and high
speed are essential and low power is critical.

With only 1.7 mA of supply current, the AD8012 also offers
exceptional ac specifications such as 20 ns settling time and
2,250 V/µs slew rate. The video specifications are 0.02% differ-
ential gain and 0.06 degree differential phase, excellent for such
a low power amplifier. In addition, the AD8012 has a low offset
of 1.5 mV.

The AD8012 is well suited for any application that requires high
performance with minimal power.

The product is available in standard 8-lead SOIC or MSOP
packages and operates over the industrial temperature range
–40°C to +85°C.

AD8012

*

FUNCTIONAL BLOCK DIAGRAM

–40

G = +2
V

= 2V p-p

OUT

= 750

R

–50

–60

–70

DISTORTION – dBc

–80

–90

10 1k100

THIRD

SECOND

RL – 

F

Figure 1. Distortion vs. Load Resistance, VS = ±5V,
Frequency = 500 kHz

+V

S

+

V

–

AMP 1

IN

–V

S

V

REF

R1

R2

Np:Ns

TRANSFORMER

RL = 100
OR

135

+

LINE

V

OUT

POWER
IN dB

–

Figure 2. Differential Drive Circuit for XDSL Applications

*Protected under U.S. Patent Number 5,537,079.

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. Trademarks and
registered trademarks are the property of their respective owners.

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 © 2003 Analog Devices, Inc. All rights reserved.

AD8012* Product Page Quick Links

Comparable Parts

View a parametric search of comparable parts

Evaluation Kits

• AD8012 Evaluation Board

• Universal Evaluation Board for Dual High Speed
Operational Amplifiers

Documentation

Application Notes

• AN-356: User's Guide to Applying and Measuring
Operational Amplifier Specifications

• AN-851: A WiMax Double Downconversion IF Sampling
Receiver Design

Data Sheet

• AD8012: Dual 350 MHz Low Power Amplifier Data Sheet

User Guides

• UG-128: Universal Evaluation Board for Dual High Speed
Op Amps in SOIC Packages

• UG-129: Universal Evaluation Board for Dual High Speed
Op Amps in MSOP Packages

• UG-886: Universal Evaluation Board for Dual High Speed
Op Amps Offered in 8-Lead MSOP

Tools and Simulations

• Analog Filter Wizard

• Analog Photodiode Wizard

• AD8012 SPICE Macro-Model

Last Content Update: 08/30/2016

Reference Materials

Analog Dialogue

• Current Feedback Amplifiers - Part 1

• Current Feedback Amplifiers - Part 2

• Two-Stage Current-Feedback Amplifier

Tutorials

• MT-034: Current Feedback (CFB) Op Amps

• MT-051: Current Feedback Op Amp Noise Considerations

• MT-057: High Speed Current Feedback Op Amps

• MT-059: Compensating for the Effects of Input Capacitance
on VFB and CFB Op Amps Used in Current-to-Voltage
Converters

Design Resources

• AD8012 Material Declaration

• PCN-PDN Information

• Quality And Reliability

• Symbols and Footprints

Discussions

View all AD8012 EngineerZone Discussions

Sample and Buy

Visit the product page to see pricing options

Technical Support

Submit a technical question or find your regional support
number

* This page was dynamically generated by Analog Devices, Inc. and inserted into this data sheet. Note: Dynamic changes to
the content on this page does not constitute a change to the revision number of the product data sheet. This content may be
frequently modified.

AD8012–SPECIFICATIONS

DUAL SUPPLY

(@ TA = 25C, VS = 5 V, G = +2, RL = 100 , RF = RG = 750 , unless otherwise noted.)

Parameter Conditions Min Typ Max Unit

DYNAMIC PERFORMANCE

–3 dB Small Signal Bandwidth G = +1, V

G=+2, V
G=+2, V

0.1 dB Bandwidth V
Large Signal Bandwidth V
Slew Rate V
Rise and Fall Time V

< 0.4 V p-p, RL = 1 kΩ/100 Ω 40/23 MHz

OUT

= 4 V p-p 75 MHz

OUT

= 4 V p-p 2,250 V/µs

OUT

= 2 V p-p 3 ns

OUT

Settling Time 0.1%, V

0.02%, V

< 0.4 V p-p, RL = 1 kΩ 270 350 MHz

OUT

< 0.4 V p-p, RL = 1 kΩ 95 150 MHz

OUT

< 0.4 V p-p, RL = 100 Ω 90 MHz

OUT

= 2 V p-p 20 ns

OUT

= 2 V p-p 35 ns

OUT

Overdrive Recovery 2⫻ Overdrive 60 ns

NOISE/HARMONIC PERFORMANCE

Distortion V

Second Harmonic 500 kHz, R

Third Harmonic 500 kHz, R

Output IP3 500 kHz, ∆f = 10 kHz, R
IMD 500 kHz, ∆f = 10 kHz, R
Crosstalk 5 MHz, R

= 2 V p-p, G = +2

OUT

5 MHz, R

5 MHz, R

= 1 kΩ/100 Ω –89/–73 dBc

L

= 1 kΩ/100 Ω –78/–62 dBc

L

= 1 kΩ/100 Ω –84/–72 dBc

L

= 1 kΩ/100 Ω –66/–52 dBc

L

= 100 Ω –70 dB

L

= 1 kΩ/100 Ω 30/40 dBm

L

= 1 kΩ/100 Ω –79/–77 dBc

L

Input Voltage Noise f = 10 kHz 2.5 nV/√Hz
Input Current Noise f = 10 kHz, +Input, –Input 15 pA/√Hz
Differential Gain f = 3.58 MHz, R

= 150 Ω/1 kΩ, G = +2 0.02/0.02 %

L

Differential Phase f = 3.58 MHz, RL = 150 Ω/1 kΩ, G = +2 0.3/0.06 Degrees

DC PERFORMANCE

Input Offset Voltage ±1.5 ±4mV

±5mV

Open-Loop Transimpedance V

T

MIN–TMAX

= ±2 V, RL = 100 Ω 240 500 kΩ

OUT

T

MIN–TMAX

200 kΩ

INPUT CHARACTERISTICS

Input Resistance +Input 450 kΩ
Input Capacitance +Input 2.3 pF
Input Bias Current +Input, –Input ±3 ±12 µA

±15 µA

Common-Mode Rejection Ratio V

+Input, –Input, T

= ±2.5 V –56 –60 dB

CM

MIN–TMAX

Input Common-Mode Voltage Range ±3.8 ±4.1 V

OUTPUT CHARACTERISTICS

Output Resistance G = +2 0.1 Ω
Output Voltage Swing ±3.85 ±4V
Output Current T

MIN–TMAX

70 125 mA

Short-Circuit Current 500 mA

POWER SUPPLY

Supply Current/Amp 1.7 1.8 mA

T

MIN–TMAX

1.9 mA

Operating Range Dual Supply ±1.5 ±6.0 V
Power Supply Rejection Ratio –58 –60 dB

Specifications subject to change without notice.

REV. B–2–

AD8012

SINGLE SUPPLY

(@ TA = 25C, VS = +5 V, G = +2, RL = 100 , RF = RG = 750 , unless otherwise noted.)

Parameter Conditions Min Typ Max Unit

DYNAMIC PERFORMANCE

–3 dB Small Signal Bandwidth G = +1, V

G=+2, V
G=+2, V

0.1 dB Bandwidth V
Large Signal Bandwidth V
Slew Rate V
Rise and Fall Time V

< 0.4 V p-p, RL = 1 kΩ/100 Ω 43/24 MHz

OUT

= 2 V p-p 60 MHz

OUT

= 3 V p-p 1,200 V/µs

OUT

= 2 V p-p 2 ns

OUT

Settling Time 0.1%, V

0.02%, V

< 0.4 V p-p, RL = 1 kΩ 220 300 MHz

OUT

< 0.4 V p-p, RL = 1 kΩ 90 140 MHz

OUT

< 0.4 V p-p, RL = 100 Ω 85 MHz

OUT

= 2 V p-p 25 ns

OUT

= 2 V p-p 40 ns

OUT

Overdrive Recovery 2⫻ Overdrive 60 ns

NOISE/HARMONIC PERFORMANCE

Distortion V

= 2 V p-p, G = +2

OUT

Second Harmonic 500 kHz, RL = 1 kΩ/100 Ω –87/–71 dBc

5 MHz, R

Third Harmonic 500 kHz, R

5 MHz, R
Output IP3 500 kHz, R
IMD 500 kHz, R
Crosstalk 5 MHz, R

= 1 kΩ/100 Ω –77/–61 dBc

L

= 1 kΩ/100 Ω –89/–72 dBc

L

= 1 kΩ/100 Ω –78/–52 dBc

L

= 1 kΩ/100 Ω 30/40 dBm

L

= 1 kΩ/100 Ω –77/–80 dBc

L

= 100 Ω –70 dB

L

Input Voltage Noise f = 10 kHz 2.5 nV/√Hz
Input Current Noise f = 10 kHz, +Input, –Input 15 pA/√Hz

Black Level Clamped to +2 V, f = 3.58 MHz
Differential Gain R

= 150 Ω/1 kΩ 0.03/0.03 %

L

Differential Phase RL = 150 Ω/1 kΩ 0.4/0.08 Degrees

DC PERFORMANCE

Input Offset Voltage ± 1 ±3mV

±4mV

Open-Loop Transimpedance V

T

MIN–TMAX

= 2 V p-p, RL = 100 Ω 200 400 kΩ

OUT

T

MIN–TMAX

150 kΩ

INPUT CHARACTERISTICS

Input Resistance +Input 450 kΩ
Input Capacitance +Input 2.3 pF
Input Bias Current +Input, –Input ±3 ±12 µA

±15 µA

Common-Mode Rejection Ratio V

+Input, –Input, T

= 1.5 V to 3.5 V –56 –60 dB

CM

MIN–TMAX

Input Common-Mode Voltage Range 1.5 to 3.5 1.2 to 3.8 V

OUTPUT CHARACTERISTICS

Output Resistance G = +2 0.1 Ω
Output Voltage Swing 1 to 4 0.9 to 4.2 V
Output Current T

MIN–TMAX

50 100 mA

Short-Circuit Current 500 mA

POWER SUPPLY

Supply Current/Amp 1.55 1.75 mA

T

MIN–TMAX

1.85 mA
Operating Range Single Supply 3 12 V
Power Supply Rejection Ratio –58 –60 dB

Specifications subject to change without notice.

REV. B

–3–

AD8012

MAXIMUM POWER DISSIPATION

The maximum power that can be safely dissipated by the AD8012
is limited by the associated rise in junction temperature. The maxi­mum safe junction temperature for plastic encapsulated devices
is determined by the glass transition temperature of the plastic,
approximately +150°C. Temporarily exceeding this limit may
cause a shift in parametric performance due to a change in the
stresses exerted on the die by the package. Exceeding a junction
temperature of +175°C for an extended period can result in
device failure.

The output stage of the AD8012 is designed for maximum load
current capability. As a result, shorting the output to common
can cause the AD8012 to source or sink 500 mA. To ensure
proper operation, it is necessary to observe the maximum power
derating curves. Direct connection of the output to either power
supply rail can destroy the device.

Test Circuits

750 750

V

IN

49.9

0.1F

0.1F

+

+

10F

10F

Test Circuit 1. Gain = +2

V

OUT

R

L

+V

S

–V

S

2.0

TJ = 150C

1.5

1.0

0.5

MAXIMUM POWER DISSIPATION – W

0

–40 –30

–50

8-LEAD SOIC

PACKAGE

8-LEAD

MSOP

010203040506070 8090

–20 –10

AMBIENT TEMPERATURE – C

Figure 3. Plot of Maximum Power Dissipation vs.
Temperature for AD8012

V

IN

750 750

53.6

0.1F

0.1F

+

+

10F

10F

V

OUT

R

L

+V

S

–V

S

Test Circuit 2. Gain = –1

REV. B–4–

AD8012

ABSOLUTE MAXIMUM RATINGS

Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12.6 V

Internal Power Dissipation

2

1

SOIC Package (R) . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.8 W

MSOP Package (RM) . . . . . . . . . . . . . . . . . . . . . . . . 0.6 W

Input Voltage (Common Mode) . . . . . . . . . . . . . . . . . . . . ±V

Differential Input Voltage . . . . . . . . . . . . . . . . . . . . . . . ± 2.5 V

Output Short-Circuit Duration

NOTES

1

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 those indicated in the operational
section of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.

2

Specification is for device in free air at +25°C.

S

8-Lead SOIC Package: ␪

8-Lead MSOP Package: ␪

= 155°C/W

JA

= 200°C/W

JA

. . . . . . . . . . . . . . . . . .Observe Power Derating Curves

Storage Temperature Range RM, R . . . . . . –65°C to +125°C

Operating Temperature Range (A Grade) . . . –40°C to +85°C

Lead Temperature Range (Soldering 10 sec) . . . . . . . . . 300°C

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
AD8012 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.

ORDERING GUIDE

Model Temperature Range Package Description Package Options Branding

AD8012AR –40°C to +85°C 8-Lead SOIC R-8
AD8012AR-REEL –40°C to +85°C13” Tape and Reel R-8
AD8012AR-REEL7 –40°C to +85°C7” Tape and Reel R-8
AD8012ARM –40°C to +85°C 8-Lead MSOP RM-08 H6A
AD8012ARM-REEL –40°C to +85°C13” Tape and Reel RM-08 H6A
AD8012ARM-REEL7 –40°C to +85°C7” Tape and Reel RM-08 H6A
AD8012ARMZ* –40°C to +85°C 8-Lead MSOP RM-08 H6A
AD8012ARMZ-REEL* –40°C to +85°C13” Tape and Reel RM-08 H6A
AD8012ARMZ-REEL7* –40°C to +85°C7” Tape and Reel RM-08 H6A

*Z = Pb-free product.

REV. B

–5–

AD8012–Typical Performance Characteristics

20mV

5ns

TPC 1. 100 mV Step Response; G = +2, VS = ±2.5 V or

±

5 V, RL = 1 kΩ*

1V

10ns

TPC 2. 4 V Step Response; G = +2, VS = ±5 V, RL = 1 k

1V 10ns

TPC 4. 4 V Step Response; G = –1, VS = ±5 V, RL = 1 k

20mV

Ω

TPC 5. 100 mV Step Response; G = +2, VS = ±2.5 V or

±

5 V, RL = 100 Ω*

5ns

Ω

20mV

5ns

TPC 3. 100 mV Step Response; G = –1, VS = ±2.5 V
or ±5 V, RL = 1 kΩ*

*VS = ± 2.5 V operation is identical to VS = +5 V single-supply operation.

500mV

10ns

TPC 6. 2 V Step Response; G = +2, VS = ±2.5 V, RL = 100

REV. B–6–

Ω

AD8012

1V

10ns

TPC 7. 4 V Step Response; G = +2, VS = ±5 V, RL = 100

20mV

5ns

TPC 8. 100 mV Step Response; G = –1, VS = ±2.5 V
or ±5 V, RL = 100 Ω*

1V

Ω

TPC 10. 4 V Step Response; G = –1, VS = ±5 V, RL = 100

–40

–50

–60

–70

DISTORTION – dBc

–80

–90

10 1k100

RL – 

THIRD

SECOND

10ns

G = +2
V

OUT

= 750

R

F

Ω

= 2V p-p

TPC 11. Distortion vs. Load Resistance; VS = ±5 V,
Frequency = 500 kHz

500mV

10ns

TPC 9. 2 V Step Response; G = –1, VS = ±2.5 V, RL = 100

REV. B

–40

THIRD

= 100

R

L

SECOND

= 100

R

THIRD

= 1k

R

L

L

G = +2

=

2V p-p

V

OUT

R

= 750

F

10 20

–60

–80

DISTORTION  dBc

–100

1

Ω

TPC 12. Distortion vs. Frequency; VS = ±5 V

SECOND
R

= 1k

L

FREQUENCY  MHz

–7–

AD8012

0.5

G = +2
VO = 0.3V p-p

R

= 750

F

= 100

R

L

= 5V

V

S

10 100

NORMALIZED GAIN  dB

–0.1

–0.2

–0.3

–0.4

–0.5

0.4

0.3

0.2

0.1

0

0.1

1

FREQUENCY  MHz

TPC 13. Gain Flatness; VS = ±5 V

–40

G = +2
V

= 2V p-p

OUT

= 750

–50

SECOND

–60

–70

DISTORTION – dBc

–80

–90

THIRD

10 1k100

RL – 

R

F

TPC 14. Distortion vs. Load Resistance; VS = +5 V,
Frequency = 500 kHz

0.5

0.4

0.3

0.2

0.1

0

–0.1

–0.2

NORMALIZED GAIN  dB

–0.3

–0.4

–0.5

0.1

1

FREQUENCY  MHz

10 100

TPC 16. Gain Flatness; VS = +5 V

5

4

3

dB

2



1

0

–1

–2

NORMALIZED GAIN

–3

–4

–5

1

G = +10

G = +2

10

FREQUENCY  MHz

TPC 17. Frequency Response; VS = ±5 V

G = +2
VO = 0.3V p-p

R

= 750

F

R

= 100

L

VS = +5V

VO = 0.3V p-p
R

= 750

F

R

= 100

L

= 5V

V

S

G = +1

100 500

–40

–60

–80

DISTORTION – dBc

–100

1

THIRD
R

SECOND

= 1k

R

L

THIRD

= 1k

R

L

FREQUENCY – MHz

= 100

L

SECOND

= 100

R

L

G = +2

= 2V p-p

V

OUT

= 750

R

F

10 20

TPC 15. Distortion vs. Frequency; VS = +5 V

OUTPUT VOLTAGE  dBV

–12

–15

–18

–21

9

6

3

1V RMS

0

–3

–6

–9

1

10

FREQUENCY  MHz

G = +2

= 750

R

F

RL = 100
V

= 5V

S

100 500

TPC 18. Output Voltage vs. Frequency; VS = ±5 V,
G = +2, RL = 100

Ω

REV. B–8–

0

0

–10

–20

–30

–40

–60

–70

–80

100k 1M 10M 100M 500M

FREQUENCY – Hz

–50

–90

–100

PSRR – dB

VS = +5V OR 5V
G = +2
R

F

= 750

–PSRR

+PSRR

–10

–20

–30

–40

–50

–60

CMRR  dB

–70

–80

–90

–100

VIN = 0.2V p-p

= 5V, +5V

V

S

FREQUENCY – MHz

10.03 0.1

10

100 500

TPC 19. CMRR vs. Frequency; VS = ±5 V, +5 V

AD8012

TPC 22. PSRR vs. Frequency; VS = ±5 V, +5 V

5

4

3

2

1

0

–1

–2

NORMALIZED GAIN  dB

–3

–4

–5

1

G = +10

10
FREQUENCY – MHz

TPC 20. Frequency Response; VS = +5 V

3

1VRMS

0

–3

–6

–9

–12

–15

–18

OUTPUT VOLTAGE  dBV

–21

–24

–27

1

10

FREQUENCY  MHz

TPC 21. Output Voltage vs. Frequency; VS = +5 V,
G = +2, RL = 100

Ω

REV. B

G = +2

VO = 0.3V p-p



R

= 750

F



R

= 100

L

V

= +5V

S

G = +1

100 500

G = +2

= 750

R

F

RL = 100
V

= +5V

S

100 500

–9–

1k

100

OUTPUT RESISTANCE  

0.01

10

1

0.1

G = +2

= 750

R

F

VS = +5V

10.03 0.1

FREQUENCY – MHz

10

VS = 5V

100 500

TPC 23. Output Resistance vs. Frequency

135

115

95

75

 dB 

Z

55

T

35

15

–5

1k 10k 100k 1M 10M 100M 1G

FREQUENCY  Hz

TZ(s)

PHASE

TPC 24. Open-Loop Transimpedance and
Phase vs. Frequency

0

–40

–80

–120

–160

–200

–240

–280

PHASE – Degrees

AD8012

Hz

INPUT VOLTAGE NOISE – nV/

4.0

3.8

3.6

3.4

3.2

3.0

2.8

2.6

2.4

2.2

2.0

9

8

7

6

5

4

SWING – V p-p

3

2

1

0

10

LOAD – 

TPC 25. Output Swing vs. Load

100

FREQUENCY – Hz

TPC 26. Noise vs. Frequency

5V

+5V

1k 10k100

CURRENT NOISE

+IN/–IN

VOLTAGE NOISE

10k1k

30

28

26

Hz

24

22

20

18

16

14

INPUT CURRENT NOISE – pA/

12

10

100k

G = +2
R

= 750

F

RL = 100
2V STEP

OUTPUT VOLTAGE ERROR – 0.1%/ DIV

0.1%

5ns

t = 0

TPC 28. Settling Time, VS = ±5 V

5

VO = 0.3V p-p
R
R

G = +2

100 500

NORMALIZED GAIN  dB

4

3

2

1

0

–1

–2

–3

–4

–5

1

G = +10

10

FREQUENCY – MHz

TPC 29. Frequency Response; VS = ±5 V

= 750

F

= 1k

L

G = +1

9

8

f = 5MHz
G = 2

7

R

= 750

F

6

5

4

3

2

1

0

PEAK-TO-PEAK OUTPUT AT 5MHz (ⱕ1% THD)  V

3 4 5 6 7 8 9 10 11

TOTAL SUPPLY VOLTAGE  V

RL = 1k

RL = 100

TPC 27. Output Swing vs. Supply

0.5

0.4

0.3

0.2

0.1

0

–0.1

–0.2

NORMALIZED GAIN – dB

–0.3

–0.4

–0.5

0.1

TPC 30. Gain Flatness; VS = ±5 V

FREQUENCY – MHz

VO = 0.3V p-p
G = +2
R

= 750

F

R

= 1k

L

101 100

REV. B–10–

INPUT REFERRED ERROR – dB

NORMALIZED GAIN – dB

0.3

–0.3

0.2

–0.1

VO = 0.3V p-p
R

F

= 750

R

L

= 1k

0.1

0

–0.2

–0.4

0.4

0.5

–0.5

FREQUENCY – MHz

0.1

101 100

–20

DRIVER

–30

–40

–50

–60

–70

–80

–90

–100

–110

–120

= 2V p-p

V

O

RL = 100

SIDE 1

10.03 0.1

FREQUENCY – MHz

TPC 31. Crosstalk vs. Frequency

SIDE 2

AD8012

10

100 500

TPC 33. Gain Flatness; VS = +5 V

5

4

3

2

1

0

NORMALIZED GAIN  dB

–1

–2

–3

–4

–5

1

G = +10

10

FREQUENCY – MHz

G = +2

100 500

TPC 32. Frequency Response; VS = +5 V

VO = 0.3V p-p



R

= 750

F



R

= 1k

L

G = +1

+3V

V

–3V

OUT

V

0V

0V

V

, 2V/DIV

OUT

IN

V

IN

V

OUT

0V

0V

20ns

TPC 34. Overdrive Recovery; VS = ±5 V, G = +2,
RF = 750Ω, RL = 100Ω, VIN = 3 V p-p (T = 1µs)

REV. B

–11–

AD8012

THEORY OF OPERATION

The AD8012 is a dual, high speed CF amplifier that attains new
levels of bandwidth (BW), power, distortion, and signal swing
capability. Its wide dynamic performance (including noise) is
the result of both a new complementary high speed bipolar
process and a new and unique architectural design. The AD8012
uses a two-gain stage complementary design approach versus
the traditional single-stage complementary mirror structure
sometimes referred to as the Nelson amplifier. Though twin
stages have been tried before, they typically consumed high
power since they were of a folded cascade design, similar to that
of the AD9617. This design allows for the standing or quiescent
current to add to the high signal or slew current-induced stages.
In the time domain, the large signal output rise/fall time and
slew rate is typically controlled by the small signal BW of the
amplifier and the input signal step amplitude, respectively, and
not the dc quiescent current of the gain stages (with the excep­tion of input level shift diodes Q1/Q2). Using two stages versus
one also allows for a higher overall gain bandwidth product
(GBWP) for the same power, resulting in lower signal distortion
and the ability to drive heavier external loads. In addition, the
second-gain stage also isolates (divides down) A3’s input
reflected load drive and the nonlinearities created, resulting in
relatively lower distortion and higher open-loop gain.

Overall, when high external load drive and low ac distortion is a
requirement, a twin-gain stage integrating amplifier like the
AD8012 will provide excellent results for lower power over the

traditional single stage complementary devices. In addition,
because the AD8012 is a CF amplifier, closed-loop BW variations
versus external gain variations (varying RN) will be much lower
compared to a VF op amp, where the BW varies inversely with
gain. Another key attribute of this amplifier is its ability to run on
a single 5 V supply partially because of its wide common-mode
input and output voltage range capability. For 5 V supply
operation, the device consumes half the quiescent power (vs.
10 V supply) with little degradation in its ac and dc perfor­mance characteristics. See data sheet comparisons.

DC GAIN CHARACTERISTICS

Gain stages A1/A1B and A2/A2B combined provide negative
feedforward transresistance gain as shown in Figure 4. Stage A3
is a unity-gain buffer that provides external load isolation to A2.
Each stage uses a symmetrical complementary design (A3 is also
complementary though not explicitly shown). This is done to
reduce both second-order signal distortion and overall quiescent
power as previously described. In the quasi dc to low frequency
region, the closed-loop gain relationship can be approximated as:

G= +R R

1//noninverting operation

FN

G=–R R

FN

inverting operation

These basic relationships are common to all traditional opera­tional amplifiers.

IPP

Q1

V

P

+ Ð

Q2

INP

CP2

A2

A2

C

D

ICQ + IO

I

V

O

A3

R

Z2

ICQ – IO

R

F

R

N

L

V

O

C

L

AD8012

C

D

A1

IPN

IQ1

Q3

V

N

Z

IE

Q4

IQ1

IPN

A1

Z1 = R1 || C1

Z1

–V

I

CP1

IR + IFC

I

IR – IFC

–V

I

Z1

CP1

Figure 4. Simplified Block Diagram

REV. B–12–

AD8012

APPLICATIONS
Line Driving for HDSL

High bitrate digital subscriber line (HDSL) is becoming
popular as a means of providing full duplex data communication at
rates up to 1.544 MBPS or 2.048 MBPS over moderate distances
via conventional telephone twisted pair wires. Traditional T1
(E1 in Europe) requires repeaters every 3,000 feet to 6,000 feet
to boost the signal strength and allow transmission over distances
of up to 12,000 feet. In order to achieve repeaterless transmission
over this distance, an HDSL modem requires a transmitted
power level of 13.5 dBm (assuming a line impedance of 135 Ω).

HDSL uses the two binary/one quaternary line code (2B1Q).
A sample 2B1Q waveform is shown in Figure 5. The digital bit
stream is broken up into groups of two bits. Four analog volt­ages (called quaternary symbols) are used to represent the four
possible combinations of two bits. These symbols are assigned
the arbitrary names +3, +1, –1, and –3. The corresponding
voltage levels are produced by a DAC that is usually part of an
analog front end circuit (AFEC). Before being applied to the
line, the DAC output is low-pass filtered and acquires the sinu­soidal form shown in Figure 5. Finally, the filtered signal is
applied to the line driver. The line voltages that correspond to
the quaternary symbols +3, +1, –1, and –3 are 2.64 V, 0.88 V,
–0.88 V, and –2.64 V. This gives a peak-to-peak line voltage of

5.28 V.

SYMBOL

VOLTAGE

NAME

+3 2.64V

+1 0.88V

–1 –0.88V

–3 –2.64V

–101+310+111–300–300+111+310–300–101–101+111–101–3

DAC
OUTPUT

FILTERED
OUTPUT
TO LINE
DRIVER

00

Figure 5. Time Domain Representation of an HDSL Signal

Many of the elements of a classic differential line driver are
shown in the HDSL line driver in Figure 6. A 6 V peak-to-peak
differential signal is applied to the input. The differential gain of
the amplifier (1+2 R

) is set to +2, so the resulting differen-

F/RG

tial output signal is 12 V p-p.

As is normal in telephony applications, a transformer galvani­cally isolates the differential amplifier from the line. In this case,
a 1:1 turns ratio is used. In order to correctly terminate the line,
it is necessary to set the output impedance of the amplifier to be
equal to the impedance of the line being driven (135 Ω in this
case). Because the transformer has a turns ratio of 1:1, the
impedance reflected from the line is equal to the line impedance
of 135 Ω (R

REFL

= R

/Turns Ratio2). As a result, two 66.5 Ω

LINE

resistors correctly terminate the line.

TO

RECEIVER

CIRCUITRY

+

6V p-p

–

TO

RECEIVER

CIRCUITRY

AD8012

1.5k

AD8012

+5V

–5V

0.1F

R

750

R

750

0.1F

F

F

12V p-p

66.5

66.5

1:1

UP TO

12,000 FEET

6V p-p

GAIN = +2

135

1:1

1/2

R

G

1/2

Figure 6. Differential for HDSL Applications

The immediate effect of back-termination is that the signal from
the amplifier is halved before being applied to the line. This
doubles the power the amplifier must deliver. However, the
back-termination resistors also play an important second role.

Full-duplex data transmission systems like HDSL simulta­neously transmit data in both directions. As a result, the signal
on the line and across the back termination resistors is the
composite of the transmitted and received signal. The termina­tion resistors are used to tap off this signal and feed it to the
receive circuitry. Because the receive circuitry “knows” what is
being transmitted, the transmitted data can be subtracted from
the digitized composite signal to reveal the received data.

Driving a line with a differential signal offers a number of
advantages compared to a single-ended drive. Because the two
outputs are always 180 degrees out of phase relative to one
another, the differential signal output is double the output
amplitude of either of the op amps. As a result, the differential
amplifier can have a peak-to-peak swing of 16 V (each op amp
can swing to ±4 V), even though the power supply is ±5 V.

In addition, even-order harmonics (second, fourth, sixth, and
so on.) of the two single-ended outputs tend to cancel out one
another, so the total harmonic distortion (quadratic sum of all
harmonics) decreases compared to the single-ended case, even
as the signal amplitude is doubled. This is particularly advan­tageous in the case of the second harmonic. Because it is very
close to the fundamental, filtering becomes difficult. In this
application, the THD is dominated by the third harmonic,
which is 65 dB below the carrier (i.e., spurious-free dynamic
range = –65 dBc).

Differential line driving also helps to preserve the integrity of the
transmitted signal in the presence of electromagnetic interfer­ence (EMI). EMI tends to induce itself equally onto both the
positive and negative signal lines. As a result, a receiver with
good common-mode rejection will amplify the original signal
while rejecting induced (common-mode) EMI.

REV. B

–13–

AD8012

Choosing the Appropriate Turns Ratio for the Transformer

Increasing the peak-to-peak output signal of the amplifier in the
previous example and adding a variation in the turns ratio of the
transformer can yield further enhancements to the circuit. The
output signal swing of the AD8012 can be increased to about
±3.9 V before clipping occurs. This increases the peak-to-peak
output of the differential amplifier to 15.6 V. Because the signal
applied to the primary winding is now bigger, the transformer
turns ratio of 1:1 can be replaced with a (step-down) turns ratio
of about 1.3:1 (from amplifier to line). This steps the 7.8 V
peak-to-peak primary voltage down to 6 V. This is the same
secondary voltage of the earlier examples, so the resulting power
delivered to the line is the same.

The received signal, which is small relative to the transmitted
signal, will, however, be stepped up by a factor of 1.3. Amplifying
the received signal in this manner enhances its signal-to-noise
ratio and is useful when the received signal is small compared to
the to-be-transmitted signal.

The impedance reflected from the 135 Ω line now becomes
228 Ω (1.3

2

⫻ 135 Ω). With a correctly terminated line, the
amplifier must now drive a total load of 456 Ω (114 Ω + 114 Ω
+ 228 Ω), considerably more than the original 270 Ω load. This
reduces the drive current from the op amps by about 40%.

More significant, however, is the reduction in dynamic power
consumption—that is, the power the amplifier must consume in
order to deliver the load power. Increasing the output signal so
that it is as close as possible to the power rails minimizes the
power consumed in the amplifier.

There is, however, a price to pay in terms of increased signal
distortion. Increasing the output signal of each op amp from the
original ± 3 V to ±3.9 V reduces the spurious-free dynamic
range (SFDR) from –65 dB to –50 dB (measured at 500 kHz),
even though the overall load impedance has increased from
270 Ω to 456 Ω.

The PCB should have a ground plane covering all unused
portions of the component side of the board to provide a low
impedance ground path. The ground plane should be removed
from the area near the input pins to reduce stray capacitance.

Chip capacitors should be used for supply bypassing (see Figure 7).
One end should be connected to the ground plane and the other
within 1/8 inch of each power pin. An additional (4.7 µF to 10 µF)
tantalum electrolytic capacitor should be connected in parallel.

The feedback resistor should be located close to the inverting
input pin in order to keep the stray capacitance at this node to
a minimum. Capacitance greater than 1.5 pF at the inverting
input will significantly affect high speed performance when
operating at low noninverting gains.

Stripline design techniques should be used for long signal traces
(greater than about 1 inch). They should be designed with the
proper system characteristic impedance and be properly termi­nated at each end.

INVERTING CONFIGURATION

R

V

G

IN

R

T

*RO CHOSEN FOR CHARACTERISTIC IMPEDANCE.

NONINVERTING CONFIGURATION

R

G

R

F

+V

S

10F

+

0.1F

R

F

RO*

RO*

V

OUT

V

OUT

LAYOUT CONSIDERATIONS

The specified high speed performance of the AD8012 requires
careful attention to board layout and component selection.
Table I shows recommended component values for the AD8012
and Figures 8–13 show recommended layouts for the 8-lead
SOIC and MSOP packages for a positive gain. Proper RF
design techniques and low parasitic component selections
are mandatory.

Table I. Typical Bandwidth vs. Gain Setting Resistors

Gain R

F

R

G

–1 750 Ω 750 Ω 53.6 Ω 110
+1 750 Ω 49.9 Ω 350
+2 750 Ω 750 Ω 49.9 Ω 150
+10 750 Ω 82.5 Ω 49.9 Ω 40

RT chosen for 50 Ω characteristic input impedance.

V

IN

R

T

*R

CHOSEN FOR CHARACTERISTIC IMPEDANCE.

O

0.1F

10F

+

–V

S

Figure 7. Inverting and Noninverting Configurations

Small Signal –3 dB BW (MHz),

R

T

VS = 5 V, RL = 1 k

REV. B–14–

AD8012

Figure 8. Universal SOIC Noninverter Top Silkscreen

Figure 9. Universal SOIC Noninverter Top

Figure 11. Universal MSOP Noninverter Top
Silkscreen

Figure 12. Universal MSOP Noninverter Top

Figure 10. Universal SOIC Noninverter Bottom

REV. B

Figure 13. Universal MSOP Noninverter Bottom

–15–

AD8012

OUTLINE DIMENSIONS

8-Lead Standard Small Outline Package [SOIC]

Narrow Body

(R-8)

Dimensions shown in millimeters and (inches)

5.00 (0.1968)

4.80 (0.1890)

4.00 (0.1574)

3.80 (0.1497)

0.25 (0.0098)

0.10 (0.0040)

COPLANARITY

0.10

CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN

85

1.27 (0.0500)

SEATING

PLANE

COMPLIANT TO JEDEC STANDARDS MS-012AA

BSC

6.20 (0.2440)

5.80 (0.2284)

41

1.75 (0.0688)

1.35 (0.0532)

0.51 (0.0201)

0.31 (0.0122)

0.25 (0.0098)

0.17 (0.0067)

0.50 (0.0196)

0.25 (0.0099)

8
0

1.27 (0.0500)

0.40 (0.0157)

C01049–0–12/03(B)

 45

8-Lead Mini Small Outline Package [MSOP]

(RM-8)

Dimensions shown in millimeters

3.00

BSC

85

3.00
BSC

1

PIN 1

0.65 BSC

0.15

0.00

0.38

0.22

COPLANARITY

0.10

COMPLIANT TO JEDEC STANDARDS MO-187AA

BSC

4

SEATING
PLANE

4.90

1.10 MAX

0.23

0.08

8
0

0.80

0.60

0.40

Revision History

Location Page

12/03—Data Sheet changed from REV. A to REV. B.

Renumbered figures and TPCs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .Universal

Updated ORDERING GUIDE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5

Updated OUTLINE DIMENSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

–16–

REV. B