AD605ARZ-R7 - Analog Devices

Dual, Low Noise, Single-Supply

Variable Gain Amplifier

AD605

Rev. F

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FEATURES

2 independent linear-in-dB channels

Input noise at maximum gain: 1.8 nV/√Hz, 2.7 pA/√Hz

Bandwidth: 40 MHz (−3 dB)

Differential input

Absolute gain range programmable

−14 dB to +34 dB (FBK shorted to OUT) through

0 dB to 48 dB (FBK open)

Variable gain scaling: 20 dB/V through 40 dB/V

Stable gain with temperature and supply variations

Single-ended unipolar gain control

Output common mode independently set

Power shutdown at lower end of gain control

Single 5 V supply

Low power: 90 mW/channel

Drives ADCs directly

APPLICATIONS

Ultrasound and sonar time-gain controls

High performance AGC systems

Signal measurement

FUNCTIONAL BLOCK DIAGRAM

PRECISION PASSIVE

INPUT ATTENUATOR

FIXED GAIN

AMPLIFIER

+34.4dB

DIFFERENTIAL

ATTENUATOR

0 TO –48.4dB

OUT

VOCM

VGN

VREF

+IN

–IN

GAIN

CONTROL

AND

SCALING

FBK

AD605

0541-001

Figure 1.

GENERAL DESCRIPTION

The AD605 is a low noise, accurate, dual-channel, linear-in-dB

variable gain amplifier (VGA), optimized for any application

requiring high performance, wide bandwidth variable gain

control. Operating from a single 5 V supply, the AD605 provides

differential inputs and unipolar gain control for ease of use.

Added flexibility is achieved with a user-determined gain range

and an external reference input that provide user-determined

gain scaling (dB/V).

The high performance linear-in-dB response of the AD605 is

achieved with the differential input, single-supply, exponential

amplifier (DSX-AMP) architecture. Each of the DSX-AMPs

comprises a variable attenuator of 0 dB to −48.4 dB followed by

a high speed, fixed-gain amplifier. The attenuator is based on a

7-stage R-1.5R ladder network. The attenuation between tap

points is 6.908 dB, and 48.360 dB for the entire ladder network.

The DSX-AMP architecture results in 1.8 nV/√Hz input noise

spectral density and accepts a ±2.0 V input signal when VOCM

is biased at VP/2.

Each independent channel of the AD605 provides a gain range

of 48 dB that can be optimized for the application. Gain ranges

between −14 dB to +34 dB and 0 dB to +48 dB can be selected

by a single resistor between Pin FBK and Pin OUT. The lower

and upper gain ranges are determined by shorting Pin FBK to

Pin OUT or leaving Pin FBK unconnected, respectively. The

two channels of the AD605 can be cascaded to provide 96 dB

of very accurate gain range in a monolithic package.

The gain control interface provides an input resistance of

approximately 2 MΩ and scale factors from 20 dB/V to 30 dB/V

for a VREF input voltage of 2.5 V to 1.67 V, respectively. Note

that scale factors up to 40 dB/V are achievable with reduced

accuracy for scales above 30 dB/V. The gain scales linearly in dB

with control voltages (VGN) of 0.4 V to 2.4 V for the 20 dB/V

scale and 0.20 V to 1.20 V for the 40 dB/V scale. When VGN is

<50 mV, the amplifier is powered down to draw 1.9 mA. Under

normal operation, the quiescent supply current of each amplifier

channel is only 18 mA.

The AD605 is available in a 16-lead PDIP and a 16-lead SOIC_N

package and is guaranteed for operation over the −40°C to +85°C

temperature range.

AD605

Rev. F | Page 2 of 24

TABLE OF CONTENTS

Features .............................................................................................. 1

Applications ....................................................................................... 1

Functional Block Diagram .............................................................. 1

General Description ......................................................................... 1

Revision History ............................................................................... 2

Specifications ..................................................................................... 3

Absolute Maximum Ratings ............................................................ 5

ESD Caution .................................................................................. 5

Pin Configuration and Function Descriptions ............................. 6

Typical Performance Characteristics (per Channel) ................... 7

Theory of Operation ...................................................................... 13

Differential Ladder (Attenuator) .............................................. 14

AC Coupling ............................................................................... 14

Gain Control Interface ............................................................... 14

Fixed Gain Amplifier and Interpolator Circuits—Applying an

Active Feedback Amplifier ........................................................ 15

Applications Information .............................................................. 16

Connecting Two Amplifiers to Double the Gain Range ....... 16

Evaluation Board ............................................................................ 18

Input Connections ..................................................................... 18

Adjusting Gain, Common-Mode, and Reference Levels ...... 18

Output Connections .................................................................. 18

Outline Dimensions ....................................................................... 21

Ordering Guide .......................................................................... 22

REVISION HISTORY

6/08—Rev. E to Rev. F

Added Evaluation Board Section ................................................. 18

Added Figure 42 and Table 4......................................................... 18

Added Figure 43 and Figure 44..................................................... 19

Added Figure 45 to Figure 50 ........................................................ 20

5/07—Rev. D to Rev. E

Changes to Table 1 ............................................................................ 5

Changes to Fixed Gain Amplifier and Interpolator Circuits—

Applying an Active Feedback Amplifier Section ........................ 15

Updated Outline Dimensions ....................................................... 18

Changes to Ordering Guide .......................................................... 19

1/06—Rev. C to Rev. D

Updated Format .................................................................. Universal

Changes to Table 2 ............................................................................ 5

Changes to Differential Ladder (Attenuator) Section ............... 14

Updated the Outline Dimensions ................................................ 18

Changes to the Ordering Guide .................................................... 19

7/04—Rev. B to Rev. C

Edits to General Description ........................................................... 1

Edits to Specifications ....................................................................... 2

Edits to Ordering Guide ................................................................... 3

Change to TPC 22 ............................................................................. 6

Updated Outline Dimensions ....................................................... 12

AD605

Rev. F | Page 3 of 24

SPECIFICATIONS

Each channel @ TA = 25°C, VS = 5 V, RS = 50 Ω, RL = 500 Ω, CL = 5 pF, VREF = 2.5 V (scaling = 20 dB/V), −14 dB to +34 dB gain range,

unless otherwise noted.

Table 1.

AD605A AD605B

Parameter Conditions Min Typ Max Min Typ Max Unit

INPUT CHARACTERISTICS

Input Resistance 175 ± 40 175 ± 40 Ω

Input Capacitance 3.0 3.0 pF

Peak Input Voltage At minimum gain 2.5 ± 2.5 2.5 ± 2.5 V

Input Voltage Noise VGN = 2.9 V 1.8 1.8 nV/√Hz

Input Current Noise VGN = 2.9 V 2.7 2.7 pA/√Hz

Noise Figure RS = 50 Ω, f = 10 MHz, VGN = 2.9 V 8.4 8.4 dB

S = 200 Ω, f = 10 MHz, VGN = 2.9 V 12 12 dB

Common-Mode Rejection Ratio f = 1 MHz, VGN = 2.65 V −20 −20 dB

OUTPUT CHARACTERISTICS

−3 dB Bandwidth Constant with gain 40 40 MHz

Slew Rate VGN = 1.5 V, output = 1 V step 170 170 V/s

Output Signal Range RL ≥ 500 Ω 2.5 ± 1.5 2.5 ± 1.5 V

Output Impedance f = 10 MHz 2 2 Ω

Output Short-Circuit Current ±40 ±40 mA

Harmonic Distortion VGN = 1 V, VOUT = 1 V p-p

HD2 f = 1 MHz −64 −64 dBc

HD3 f = 1 MHz −68 −68 dBc

HD2 f = 10 MHz −51 −51 dBc

HD3 f = 10 MHz −53 −53 dBc

Two-Tone Intermodulation

Distortion (IMD)

RS = 0 Ω, VGN = 2.9 V, VOUT = 1 V p-p

f = 1 MHz −72 −72 dBc

f = 10 MHz −60 −60 dBc

1 dB Compression Point f = 10 MHz, VGN = 2.9 V, output referred 15 15 dBm

Third-Order Intercept f = 10 MHz, VGN = 2.9 V,

VOUT = 1 V p-p, input referred

−1 −1 dBm

Channel-to-Channel Crosstalk Ch1: VGN = 2.65 V, inputs shorted,

Ch2: VGN = 1.5 V (mid gain),

f = 1 MHz, VOUT = 1 V p-p

−70 −70 dB

Group Delay Variation 1 MHz < f < 10 MHz, full gain range ±2.0 ±2.0 ns

VOCM Input Resistance 45 45 kΩ

ACCURACY

Absolute Gain Error

−14 dB to −11 dB 0.25 V < VGN < 0.40 V −1.2 +1.0 +3.0 –1.2 +0.75 +3.0 dB

−11 dB to +29 dB 0.40 V < VGN < 2.40 V −1.0 ±0.3 +1.0 –1.0 ±0.2 +1.0 dB

+29 dB to +34 dB 2.40 V < VGN < 2.65 V −3.5 −1.25 +1.2 –3.5 −1.25 +1.2 dB

Gain Scaling Error 0.4 V < VGN < 2.4 V ±0.25 ±0.25 dB/V

Output Offset Voltage VREF = 2.500 V, VOCM = 2.500 V −30 ±20 +30 –30 ±20 +30 mV

Output Offset Variation VREF = 2.500 V, VOCM = 2.500 V 30 57 30 50 mV

AD605

Rev. F | Page 4 of 24

AD605A AD605B

Parameter Conditions Min Typ Max Min Typ Max Unit

GAIN CONTROL INTERFACE

Gain Scaling Factor VREF = 2.5 V, 0.4 V < VGN < 2.4 V 19 20 21 19 20 21 dB/V

REF = 1.67 V 30 30 dB/V

Gain Range FBK short to OUT −14 to +34 −14 to +34 dB

FBK open 0 to 48 0 to 48 dB

Input Voltage (VGN) Range 20 dB/V, VREF = 2.5 V 0.1 to 2.9 0.1 to 2.9 V

Input Bias Current −0.4 −0.4 µA

Input Resistance 2 2 MΩ

Response Time 48 dB gain change 0.2 0.2 µs

POWER SUPPLY

Supply Voltage 4.5 5.0 5.5 4.5 5.0 5.5 V

Power Dissipation 90 90 mW

VREF Input Resistance 10 10 kΩ

Quiescent Supply Current VPOS 18 23 18 23 mA

Power-Down VPOS, VGN < 50 mV 1.9 3.0 1.9 3.0 mA

Power-Up Response Time 48 dB gain, VOUT = 2 V p-p 0.6 0.6 µs

Power-Down Response Time 0.4 0.4 µs

AD605

Rev. F | Page 5 of 24

ABSOLUTE MAXIMUM RATINGS

Table 2.

Parameter Rating

Supply Voltage +VS

Pin 12, Pin 13 (with Pin 4, Pin 5 = 0 V) 6.5 V

Input Voltage Pin 1 to Pin 3, Pin 6 to Pin 9, Pin 16 VPOS, 0 V

Internal Power Dissipation

16-Lead PDIP 1.4 W

16-Lead SOIC_N 1.2 W

Operating Temperature Range −40°C to +85°C

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

Lead Temperature, Soldering 60 sec 300°C

Thermal Resistance θJA

16-Lead PDIP 85°C/W

16-Lead SOIC_N 100°C/W

Stresses above those listed under Absolute Maximum Ratings

may cause permanent 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.

ESD CAUTION

AD605

Rev. F | Page 6 of 24

PIN CONFIGURATION AND FUNCTION DESCRIPTIONS

5TOP VIEW

(Not to Scale)

AD605

VGN1

VPOS

FBK1

OUT1

VREF

–IN1

+IN1

GND1

OUT2

FBK2

VPOS

GND2

+IN2

–IN2

VGN2 VOCM

00541-002

Figure 2. Pin Configuration

Table 3. Pin Function Descriptions

Pin No. Mnemonic Description

1 VGN1 CH1 Gain Control Input and Power-Down Pin. If grounded, device is off; otherwise, positive voltage increases gain.

2 −IN1 CH1 Negative Input.

3 +IN1 CH1 Positive Input.

4 GND1 Ground.

5 GND2 Ground.

6 +IN2 CH2 Positive Input.

7 −IN2 CH2 Negative Input.

8 VGN2 CH2 Gain Control Input and Power-Down Pin. If grounded, device is off; otherwise, positive voltage increases gain.

9 VOCM Input to This Pin Defines Common-Mode Voltage for OUT1 and OUT2.

10 OUT2 CH2 Output.

11 FBK2 Feedback Pin That Selects Gain Range of CH2.

12 VPOS Positive Supply.

13 VPOS Positive Supply.

14 FBK1 Feedback Pin That Selects Gain Range of CH1.

15 OUT1 CH1 Output.

16 VREF Input to This Pin Sets Gain Scaling for Both Channels: 2.5 V = 20 dB/V and 1.67 V = 30 dB/V.

AD605

Rev. F | Page 7 of 24

TYPICAL PERFORMANCE CHARACTERISTICS (PER CHANNEL)

VREF = 2.5 V (20 dB/V scaling), f = 1 MHz, RL = 500 Ω, CL = 5 pF, TA = 25°C, VSS = 5 V.

–20

–10

00541-003

VGN (V)

GAIN (dB)

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

–40°C, +25°C, +85°C

Figure 3. Gain vs. VGN

VGN (V)

GAIN (dB)

–20

–10

FBK (OPEN)

FBK (SHORT)

00541-004

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

Figure 4. Gain vs. VGN for Different Gain Ranges

30dB/V

REF

= 1.67V)

20dB/V

REF

= 2.50V)

ACTUAL ACTUAL

–20

–10

00541-005

VGN (V)

GAIN (dB)

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

Figure 5. Gain vs. VGN for Different Gain Scalings

GAIN SCALING (dBV)

40.0

37.5

20.0

30.0

27.5

25.0

22.5

35.0

32.5

THEORETICAL

ACTUAL

VREF (V)

1.25 1.50 1.75 2.00 2.25 2.50

00541-006

Figure 6. Gain Scaling vs. VREF

GAIN ERROR (dB)

3.0

2.5

–3.0

0.2 0.7 1.2 1.7 2.2 2.7

–1.0

–1.5

–2.0

–2.5

2.0

1.0

1.5

–0.5

0.5

VGN (V)

+25°C

+85°C

–40°C

00541-007

Figure 7. Gain Error vs. VGN at Three Temperatures

VGN (V)

GAIN ERROR (dB)

2.0

1.5

–2.0

0.2 0.7 1.2 1.7 2.2 2.7

–0.5

–1.0

–1.5

1.0

0.5

f = 5MHz

f = 10MHz

00541-008

f = 1MHz

Figure 8. Gain Error vs. VGN at Three Frequencies

AD605

Rev. F | Page 8 of 24

VGN (V)

GAIN ERROR

2.0

1.0

1.5

0.5

–0.5

–1.0

–1.5

–2.0

0.2 0.7 1.71.2 2.2 2.7

00541-009

20dB/V

REF

= 2.50V

30dB/V

REF

= 1.67V

Figure 9. Gain Error vs. VGN for Two Gain Scale Values

DELTA GAIN (dB)

PERCENTAGE

–0.8 –0.6 –0.4 –0.2 0 0.2 0.4 0.6 0.8

ΔG(dB) = G(CH1) – G(CH2)

N = 50

00541-010

Figure 10. Gain Match, VGN1 = VGN2 = 1.0 V

00541-011

DELTA GAIN (dB)

PERCENTAGE

0–0.8 –0.6 –0.4 –0.2 0 0.2 0.4 0.6 0.8

ΔG(dB) = G(CH1) – G(CH2)

N = 50

Figure 11. Gain Match, VGN1 = VGN2 = 2.50 V

FREQUENCY (Hz)

GAIN (dB)

–60

–20

–40

VGN = 2.9V (FBK = OPEN)

VGN = 2.9V (FBK = SHORT)

VGN = 1.5V (FBK = OPEN)

VGN = 1.5V (FBK = SHORT)

VGN = 0.1V (FBK = OPEN)

VGN = 0.1V (FBK = SHORT)

VGN = 0.0V

00541-013

100k 1M 10M 100M

Figure 12. AC Response for Three Values of VGN

VGN (V)

(V)

2.525

2.475

2.520

2.495

2.490

2.485

2.480

2.515

2.510

2.500

2.505

OCM

= 2.50V

–40°C

+25°C

+85°C

00541-014

0.5 1.0 1.5 2.0 2.5 3.0

Figure 13. Output Offset vs. VGN at Three Temperatures

00541-015

VGN (V)

130

125

110

105

100

120

115

0 0.5 1.0 1.5 2.0 2.5 3.0

+85°C

+25°C

NOISE (nV/ Hz)

–40°C

Figure 14. Output Referred Noise vs. VGN at Three Temperatures

AD605

Rev. F | Page 9 of 24

VGN (V)

1000

100

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

NOISE (nV/ Hz)

00541-016

Figure 15. Input Referred Noise vs. VGN

TEMPERATURE (°C)

2.00

1.75

1.60

1.95

1.80

1.70

1.65

1.90

1.85

VGN = 2.9V

NOISE (nV/ Hz)

00541-017

–40 –20–30 –10 0 2010 40 605030 8070 90

Figure 16. Input Referred Noise vs. Temperature

FREQUENCY (Hz)

1.90

1.85

1.60

1.80

1.75

1.70

1.65

VGN = 2.9V

NOISE (nV/ Hz)

00541-018

100k 1M 10M

Figure 17. Input Referred Noise vs. Frequency

SOURCE

(Ω)

1k101100

VGN = 2.9V

SOURCE

ALONE

NOISE (nV/ Hz)

00541-019

100

1.0

0.1

Figure 18. Input Referred Noise vs. RSOURCE

NOISE FIGURE (dB)

1k110010

VGN = 2.9V

00541-020

SOURCE

(Ω)

Figure 19. Noise Figure vs. RSOURCE

VGN (V)

NOISE FIGURE (dB)

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

00541-021

= 50Ω

Figure 20. Noise Figure vs. VGN

AD605

Rev. F | Page 10 of 24

FREQUENCY (Hz)

HARMONIC DISTORTION (dBc)

–

–35

–70

–50

–55

–65

–60

–40

–45

HD2

HD3

100k 1M 10M 100M

00541-022

OUT

= 1V p-p

VGN = 1.0V

Figure 21. Harmonic Distortion vs. Frequency

VGN (V)

HARMONIC DISTORTION (dBc)

–

–75

–55

–60

–65

–70

–40

–50

–45 HD3

(10MHz)

HD2

(10MHz)

HD2

(1MHz)

HD3

(1MHz)

00541-023

0.5 1.1 1.40.8 1.7 2.0 2.3 2.6 2.9

Figure 22. Harmonic Distortion vs. VGN at 1 MHz and 10 MHz

FREQUENCY (MHz)

OUT

(dBm)

–

–90

–120

–30

–80

–100

–110

–60

–70

–40

–50

00541-024

9.92 9.96 10.00 10.02 10.04

f = 10MHz

OUT

= 1V p-p

VGN = 1.0V

Figure 23. Intermodulation Distortion

–20

–5

–10

–15

FREQ = 10MHz

FREQ = 1MHz

INPUT GENERATOR

LIMIT = 21dBm

00541-025

VGN (V)

(dBm)

0.1 2.92.52.11.71.30.90.5

Figure 24. 1 dB Compression vs. VGN

–5

OUT

= 1V p-p

f = 1MHz

f = 10MHz

00541-026

VGN (V)

INTERCEPT (dBm)

0.6 1.0 1.4 1.8 2.2 2.6 3.0

Figure 25. Third-Order Intercept vs. VGN at 1 MHz and 10 MHz

100ns/DIV

–400mV/DI

OUT

= 2V p-p

VGN = 1.5V

253ns 1.253µs

TRIG'D

00541-027

Figure 26. Large Signal Pulse Response

AD605

Rev. F | Page 11 of 24

100ns/DIV

40mV (DIV)

OUT

= 200mV p-p

VGN = 1.5V

200

–200

253ns 1.253µs

TRIG'D

00541-028

Figure 27. Small Signal Pulse Response

VGN (V)

2.9V

0.0V

100

500mV

200ns

500mV

00541-029

Figure 28. Power-Up/Power-Down Response

VGN (V)

2.9V

0.1V

100

500mV

100ns

500mV

0541-030

Figure 29. Gain Response

FREQUENCY (Hz)

CROSSTALK (dB)

VGN1 = 1V

OUT1

= 1V p-p

IN2

= GND

VGN2 = 2.9V

VGN2 = 2.5V VGN2 = 2.0V

VGN2 = 0.1V

00541-031

–

–40

–60

–50

–70

–80

–90

100k 1M 10M 100M

Figure 30. Crosstalk (CH1 to CH2) vs. Frequency for Four Values of VGN2

–10

–60

–20

–30

–50

–40

CMRR (dB)

= 0dBm

VGN = 2.9V

VGN = 2.5V

VGN = 2.0V

VGN = 0.1V

00541-032

FREQUENCY (Hz)

100k 1M 10M 100M

Figure 31. CMRR vs. Frequency for Four Values of VGN

FREQUENCY (Hz)

INPUT IMPEDANCE (Ω)

180

175

140

160

155

145

150

170

165

VGN = 2.9V

00541-033

100k 1M 10M 100M

Figure 32. Input Impedance vs. Frequency

AD605

Rev. F | Page 12 of 24

TEMPERATURE (°C)

SUPPLY CURRENT (mA)

00541-034

–40 –20 0 2010–10–30 40 60 80705030 90

(AD605)

(VGN = 0)

Figure 33. Supply Current (One Channel) vs. Temperature

FREQUENCY (Hz)

GROUP DELAY (ns)

VGN = 0.1V

VGN = 2.9V

00541-035

100k 1M 10M 100M

Figure 34. Group Delay vs. Frequency

AD605

Rev. F | Page 13 of 24

THEORY OF OPERATION

The AD605 is a dual-channel, low noise VGA. Figure 35 shows

the simplified block diagram of one channel. Each channel consists

of a single-supply X-AMP® (hereafter called DSX, differential

single-supply X-AMP) comprising the following:

• Precision passive attenuator (differential ladder)

• Gain control block

• VOCM buffer with supply splitting resistors R3 and R4

• Active feedback amplifier1 (AFA) with gain setting resistors

R1 and R2

The linear-in-dB gain response of the AD605 can generally be

described by Equation 1.

G (dB) = (Gain Scaling (dB/V)) × (Gain Control (V)) −

(19 dB − (14 dB) × (FB)) (1)

where:

FB = 0, if FBK to OUT is shorted.

FB = 1, if FBK to OUT is open.

Each channel provides between −14 dB to +34.4 dB through

0 dB to +48.4 dB of gain, depending on the value of the resistance

connected between Pin FBK and Pin OUT. The center 40 dB of

gain is exactly linear-in-dB while the gain error increases at the top

and bottom of the range. The gain is set by the gain control voltage

(VGN). The VREF input establishes the gain scaling. The useful

gain scaling range is between 20 dB/V and 40 dB/V for a VREF

voltage of 2.5 V and 1.25 V, respectively. For example, if FBK to

OUT is shorted and VREF is set to 2.50 V (to establish a gain

scaling of 20 dB/V), the gain equation simplifies to

G (dB) = (20 (dB/V)) × (VGN (V)) – 19 dB (2)

The desired gain can then be achieved by setting the unipolar

gain control (VGN) to a voltage within its nominal operating

range of 0.25 V to 2.65 V (for 20 dB/V gain scaling). The gain is

monotonic for a complete gain control range of 0.1 V to 2.9 V.

Maximum gain can be achieved at a VGN of 2.9 V.

Because the two channels are identical, only Channel 1 is used

to describe their operation. VREF and VOCM are the only inputs

that are shared by the two channels, and because they are normally

ac grounds, crosstalk between the two channels is minimized.

For the highest gain scaling accuracy, VREF should have an

external low impedance voltage source. For low accuracy 20 dB/V

applications, the VREF input can be decoupled with a capacitor

to ground. In this mode, the gain scaling is determined by the

midpoint between +VCC and GND; therefore, care should be

taken to control the supply voltage to 5 V. The input resistance

looking into the VREF pin is 10 kΩ ± 20%.

The AD605 is a single-supply circuit, and the VOCM pin is used

to establish the dc level of the midpoint of this portion of the

circuit. VOCM needs only an external decoupling capacitor to

ground to center the midpoint between the supply voltages (5 V,

GND). However, if the dc level of the output is important to the

user (see the Applications Information section of the AD9050

data sheet for an example), VOCM can be specifically set. The

input resistance looking into the VOCM pin is 45 kΩ ± 20%.

1 To understand the active-feedback amplifier topology, refer to the AD830

data sheet. The AD830 is a practical implementation of the idea.

820Ω

VREF

VGN

VPOS

OCM

200kΩ

OUT

DISTRIBUTED g

175Ω

GAIN

CONTROL

20Ω

200kΩ

EXT

+IN

–IN

FBK

3.36kΩ

DIFFERENTIAL

ATTENUATOR

EXT

00541-036

Figure 35. Simplified Block Diagram of a Single Channel of the AD605

AD605

Rev. F | Page 14 of 24

1.5R

R RRRRR R

RRRRRRR

–

6.908dB

–

13.82dB

–

20.72dB

–

27.63dB

–

34.54dB

–

41.45dB

–

48.36dB

+IN

MID

–IN

NOTE: R = 96Ω

1.5R = 144Ω

175Ω

00541-037

Figure 36. R-1.5R Dual Ladder Network

DIFFERENTIAL LADDER (ATTENUATOR)

The attenuator before the fixed gain amplifier is realized by a

differential, 7-stage, R-1.5R resistive ladder network with an

untrimmed input resistance of 175 Ω single ended or 350 Ω

differentially. The signal applied at the input of the ladder

network is attenuated by 6.908 dB per tap; therefore, the

attenuation at the first tap is 6.908 dB, at the second, 13.816 dB,

and so on all the way to the last tap where the attenuation is

48.356 dB (see Figure 36). A unique circuit technique is used to

interpolate continuously between the tap points, thereby providing

continuous attenuation from 0 dB to −48.36 dB. One can think

of the ladder network together with the interpolation mechanism

as a voltage-controlled potentiometer.

Because the DSX is a single-supply circuit, some means of

biasing its inputs must be provided. Node MID together with

the VOCM buffer performs this function. Without internal

biasing, external biasing is required. If not done carefully, the

biasing network can introduce additional noise and offsets. By

providing internal biasing, the user is relieved of this task and

only needs to ac couple the signal into the DSX. It should be

made clear again that the input to the DSX is still fully differential if

driven differentially, that is, Pin +IN and Pin −IN see the same

signal but with opposite polarity. What changes is the load seen

by the driver; it is 175 Ω when each input is driven single ended,

but 350 Ω when driven differentially. This can be easily explained

when thinking of the ladder network as two 175 Ω resistors

connected back-to-back with the middle node, MID, being

biased by the VOCM buffer. A differential signal applied between

nodes +IN and −IN results in zero current into Node MID, but

a single-ended signal applied to either input +IN or −IN, while the

other input is ac grounded, causes the current delivered by the

source to flow into the VOCM buffer via Node MID.

A feature of the X-AMP architecture is that the output-referred

noise is constant vs. gain over most of the gain range. Referring

to Figure 36, the tap resistance is approximately equal for all

taps within the ladder, excluding the end sections. The resistance

seen looking into each tap is 54.4 Ω, which makes 0.95 nV/√Hz of

Johnson noise spectral density. Because there are two attenuators,

the overall noise contribution of the ladder network is √2 times

0.95 nV/√Hz or 1.34 nV/√Hz, a large fraction of the total DSX

noise. The rest of the DSX circuit components contribute another

1.20 nV/√Hz, which together with the attenuator produces

1.8 nV/√Hz of total DSX input referred noise.

AC COUPLING

The DSX is a single-supply circuit; therefore, its inputs need to

be ac-coupled to accommodate ground-based signals. External

Capacitor C1 and Capacitor C2 in Figure 35 level-shift the input

signal from ground to the dc value established by VOCM (nominal

2.5 V). C1 and C2, together with the 175 Ω looking into each of

DSX inputs (+IN and −IN), act as high-pass filters with corner

frequencies depending on the values chosen for C1 and C2. For

example, if C1 and C2 are 0.1 µF, together with the 175 Ω input

resistance of each side of the differential ladder of the DSX, a −3 dB

high-pass corner at 9.1 kHz is formed.

If the DSX output needs to be ground referenced, another ac

coupling capacitor is required for level shifting. This capacitor also

eliminates any dc offsets contributed by the DSX. With a nominal

load of 500 Ω and a 0.1 µF coupling capacitor, this adds a high-pass

filter with −3 dB corner frequency at about 3.2 kHz.

The choice for all three of these coupling capacitors depends on

the application. They should allow the signals of interest to pass

unattenuated, while at the same time, they can be used to limit

the low frequency noise in the system.

GAIN CONTROL INTERFACE

The gain control interface provides an input resistance of

approximately 2 MΩ at Pin VGN1 and gain scaling factors from

20 dB/V to 40 dB/V for VREF input voltages of 2.5 V to 1.25 V,

respectively. The gain varies linearly in decibels for the center

40 dB of gain range, that is, for VGN equal to 0.4 V to 2.4 V for

the 20 dB/V scale and 0.25 V to 1.25 V for the 40 dB/V scale.

Figure 37 shows the ideal gain curves when the FBK-to-OUT

connection is shorted as described by the following equations:

G (20 dB/V) = 20 × VGN − 19, VREF = 2.500 V (3)

G (30 dB/V) = 30 × VGN − 19, VREF = 1.6666 V (4)

G (40 dB/V) = 40 × VGN − 19, VREF = 1.250 V (5)

The equations show that all gain curves intercept at the same

−19 dB point; this intercept is 14 dB higher (−5 dB) if the FBK-

to-OUT connection is left open. Outside the central linear

range, the gain starts to deviate from the ideal control law but

still provides another 8.4 dB of range. For a given gain scaling,

one can calculate VREF as

ScaleGain

VREF

dB/V20V2.500

= (6)

AD605

Rev. F | Page 15 of 24

–5

–10

–15

–20

GAIN (dB)

40dB/V 30dB/V 20dB/V

LINEAR-IN-dB RANGE

OF AD605

1.00.5 1.5 2.0 2.5 3.0

GAIN CONTROL VOLTAGE

0541-038

Figure 37. Ideal Gain Curves vs. VREF

Usable gain control voltage ranges are 0.1 V to 2.9 V for the

20 dB/V scale and 0.1 V to 1.45 V for the 40 dB/V scale. VGN

voltages of less than 0.1 V are not used for gain control because

below 50 mV the channel is powered down. This can be used to

conserve power and at the same time gate-off the signal. The

supply current for a powered-down channel is 1.9 mA, and the

response time to power the device on or off is less than 1 µs.

FIXED GAIN AMPLIFIER AND INTERPOLATOR

CIRCUITS—APPLYING AN ACTIVE FEEDBACK

AMPLIFIER

A typical X-amp architecture is powered by a dual polarity

power supply. Because the AD605 operates from a single supply, a

supply common equal to half the value of the supply voltage is

required. An active feedback amplifier (AFA) is used to provide

a differential input and to implement the feedback loop. The

AFA in the AD605 is an op amp with two gm stages; one is used

in the feedback path, and the other is used as a highly linear

differential input.

A multisection distributed gm stage senses the voltages on the

ladder network, one stage for each of the ladder nodes. Only a

few of the stages are active at any time and are dependent on the

gain control voltage.

The AFA makes a differential input structure possible because

one of its inputs (G1) is fully differential; this input is made

up of a distributed gm stage. The second input (G2) is used for

feedback. The output of G1 is some function of the voltages

sensed on the attenuator taps that is applied to a high gain

amplifier (A0). Because of negative feedback, the differential

input to the high gain amplifier is zero; this in turn implies that

the differential input voltage to G2 times gm2 (the transconductance

of G2) is equal to the differential input voltage to G1 times gm1

(the transconductance of G1). Therefore, the overall gain

function of the AFA is

R2R1

ATTEN

OUT

×=

1 (7)

where:

VOUT is the output voltage.

VATTEN is the effective voltage sensed on the attenuator.

(R1 + R2)/R2 = 42.

gm1/gm2 = 1.25; the overall gain is therefore 52.5 (34.4 dB).

The AFA has additional features that include the following:

inverting the output signal by switching the positive and negative

input to the ladder network; the possibility of using the −IN

input as a second signal input; and independent control of the

DSX common-mode voltage. Under normal operating conditions,

it is best to connect a decoupling capacitor to Pin VOCM, in

which case, the common- mode voltage of the DSX is half of

the supply voltage; this allows for maximum signal swing.

Nevertheless, the common-mode voltage can be shifted up or

down by directly applying a voltage to VOCM. It can also be

used as another signal input, the only limitation being the

rather low slew rate of the VOCM buffer.

If the dc level of the output signal is not critical, another coupling

capacitor is normally used at the output of the DSX; again, this

is done for level shifting and to eliminate any dc offsets contributed

by the DSX (see the AC Coupling section).

The gain range of the DSX is programmable by a resistor connected

between Pin FBK and Pin OUT. The possible ranges are −14 dB to

+34.4 dB when the pins are shorted together or 0 dB to +48.4 dB

when FBK is left open. For the higher gain range, the bandwidth

of the amplifier is reduced by a factor of five to about 8 MHz

because the gain increased by 14 dB. This is the case for any

constant gain bandwidth product amplifier that includes the

active feedback amplifier.

AD605

Rev. F | Page 16 of 24

APPLICATIONS INFORMATION

The basic circuit in Figure 38 shows the connections for one

channel of the AD605 with a gain range of −14 dB to +34.4 dB.

The signal is applied at +IN1. The ac coupling capacitors before

Pin −IN1 and Pin +IN1 should be selected according to the

required lower cutoff frequency. In this example, the 0.1 µF

capacitors, together with the 175 Ω of each of the DSX input

pins, provide a −3 dB high-pass corner of about 9.1 kHz. The

upper cutoff frequency is determined by the amplifier and is

40 MHz.

VREF

GND1

+IN1

–IN1

VGN1

OUT1

FBK1

VPOS

–IN2

+IN2

GND2 VPOS

FBK2

OUT2

VOCM

VGN2

AD605

VGN

0.1µF

OUT

2.500V

0541-039

Figure 38. Basic Connections for a Single Channel

As shown in Figure 38, the output is ac-coupled for optimum

performance. In the case of connecting to the 10-bit, 40 MSPS

ADC, AD9050, ac coupling can be eliminated as long as

Pin VOCM is biased by the same 3.3 V common-mode voltage

as the AD9050.

Pin VREF requires a voltage of 1.25 V to 2.5 V, with gain scaling

between 40 dB/V and 20 dB/V, respectively. Voltage VGN controls

the gain; its nominal operating range is from 0.25 V to 2.65 V

for 20 dB/V gain scaling and 0.125 V to 1.325 V for 40 dB/V

scaling. When this pin is taken to ground, the channel powers

down and disables its output.

CONNECTING TWO AMPLIFIERS TO DOUBLE THE

GAIN RANGE

Figure 39 shows the two channels of the AD605 connected in

series to provide a total gain range of 96.8 dB. When R1 and R2

are shorts, the gain range is from −28 dB to +68.8 dB with a

slightly reduced bandwidth of about 30 MHz. The reduction in

bandwidth is due to two identical low-pass circuits being connected

in series; in the case of two identical single-pole, low-pass filters,

the bandwidth is reduced by exactly √2. If R1 and R2 are

replaced by open circuits, that is, Pin FBK1 and Pin FBK2 are left

unconnected, the gain range shifts up by 28 dB to 0 dB to 96.8 dB.

As previously noted, the bandwidth of each individual channel is

reduced by a factor of 5 to about 8 MHz because the gain increased

by 14 dB. In addition, there is still the √2 reduction because the

series connection of the two channels results in a final

bandwidth of the higher gain version of about 6 MHz.

VREF

GND1

+IN1

–IN1

VGN1

OUT1

FBK1

VPOS

–IN2

+IN2

GND2 VPOS

FBK2

OUT2

VOCM

VGN2

AD605

0.1µF

VGN

VIN

OUT

2.500V

0.1µF

0.1µF C6

0.1µF

00541-040

Figure 39. Doubling the Gain Range with Two Amplifiers

Two other easy combinations are possible to provide a gain

range of −14 dB to +82.8 dB: make R1 a short and R2 an open,

or make R1 an open and R2 a short. The bandwidth for both of

these cases is dominated by the channel that is set to the higher

gain and is about 8 MHz. From a noise standpoint, the second

choice is the best because by increasing the gain of the first

amplifier, the noise of the second amplifier has less of an impact

on the total output noise. One further observation regarding

noise is that by increasing the gain, the output noise increases

proportionally; therefore, there is no increase in signal-to-noise

ratio. It actually stays fixed.

It should be noted that by selecting the appropriate values of R1

and R2, any gain range between −28 dB to +68.8 dB and 0 dB to

+96.8 dB can be achieved with the circuit in Figure 39. When

using any value other than shorts and opens for R1 and R2, the

final value of the gain range depends on the external resistors

matching the on-chip resistors. Because the internal resistors

can vary by as much as ±20%, the actual values for a particular

gain have to be determined empirically. Note that the two channels

within one part match quite well; therefore, R1 tracks R2 in

Figure 39.

C3 is not required because the common-mode voltage at

Pin OUT1 should be identical to the one at Pin +IN2 and

Pin −IN2. However, because only 1 mV of offset at the output

of the first DSX introduces an offset of 53 mV when the second

DSX is set to the maximum gain of the lowest gain range (34.4 dB),

and 263 mV when set to the maximum gain of the highest gain

range (48.4 dB), it is important to include ac coupling to get the

maximum dynamic range at the output of the cascaded amplifiers.

C5 is necessary if the output signal needs to be referenced to any

common-mode level other than half of the supply as is provided

by Pin OUT2.

AD605

Rev. F | Page 17 of 24

Figure 40 shows the gain vs. VGN for the circuit in Figure 39

at 1 MHz and the lowest gain range (−14 dB to +34.4 dB). Note

that the gain scaling is 40 dB/V, double the 20 dB/V of an

individual DSX; this is the result of the parallel connection of

the gain control inputs, VGN1 and VGN2. The gain can also be

sequentially increased by first increasing the gain of Channel 1

and then Channel 2. In this case, VGN1 and VGN2 are driven

from separate voltage sources, for instance two separate DACs.

Figure 41 shows the gain error of Figure 39.

–40

f = 1MHz

ACTUAL

–10

–20

–30

00541-041

VGN (V)

GAIN (dB)

THEORETICAL

0.1 0.5 0.9 1.3 1.7 2.1 2.5 2.9

Figure 40. Gain vs. VGN for the Circuit in Figure 39

VGN (V)

GAIN ERROR (dB)

–4

–1

–2

–3

f = 1MHz

00541-042

0.2 0.7 1.2 1.7 2.2 2.7

Figure 41. Gain Error vs. VGN for the Circuit in Figure 39

AD605

Rev. F | Page 18 of 24

EVALUATION BOARD

The AD605-EVALZ provides a platform for the circuit designer

to become familiar with the many operating and performance

features of the AD605 variable gain amplifier. It is a factory-

designed, surface-mount assembly fully tested and ready for

service. Figure 42 is a photograph of the AD605-EVALZ. Multiple

inputs, test points, and jumpers provide circuit configurations that

support any of the operating options of the device. Figure 43 is a

schematic of the board.

Power is required from only a single 5 V supply capable of

supplying 55 mA to 60 mA quiescent current.

00541-043

Figure 42. AD605–EVALZ Evaluation Board

INPUT CONNECTIONS

The AD605 VGA accepts differential or single-ended input

signals and provides single-ended outputs. The SMA connectors

enable either configuration to be used, as well as the output and

gain control signals. Each of the I/O ports is also available at a

test-loop labeled for easy identification.

The input resistance at each of the four input SMA connectors is

50 , consisting of the 175 Ω, ±40 Ω resistance of the attenuator

ladder network in parallel with the external 69.8 Ω resistors. For

single-ended operation, unused inputs can be left disconnected

or optional jumpers installed. Either VGA input is usable; for

noninverting operation, the INPx is used, and for signal inversion,

the INMx is used.

ADJUSTING GAIN, COMMON-MODE, AND

REFERENCE LEVELS

The gain of each channel is adjusted with trimmers, GN1ADJ and

GN2ADJ. Trimmer VREF ADJ adjusts the gain scaling in dB/V (or

gain slope), and VOCM ADJ adjusts the output common-mode

voltage for both channels. For dynamic gain control, JP1 and

JP4 can be removed and the signal applied at the SMA

connectors, GN1 and GN2.

OUTPUT CONNECTIONS

SMA connectors, OUT1 and OUT2, are the output connectors.

Series resistors and capacitors are included for termination and

dc blocking purposes. The output of the AD605 has a common-

mode value of one-half the supply (unless amended by a voltage

applied to the VCM pin).

Table 4 lists jumpers and their functions, and Figure 44 shows

the evaluation board in a typical test configuration.

Table 4. Table of Jumpers

Jumper Function Default Configuration

JP1 Connects trimmer GN1ADJ to pin VGN1. This jumper can be removed for an ac signal at VGN1. Installed

JP2 Grounds the IN1 pin via C2. User supplied

JP3 Grounds the IN2 pin via C5. User supplied

JP4 Connects trimmer GN2ADJ to Pin VGN2. This jumper can be removed for an ac signal at VGN2. Installed

JP5 Connects trimmer VOCMADJ to the VOCM pin. This jumper can be removed for the half supply default VOCM. Installed

JP6 Shifts the gain of Channel 2 up or down by 14 dB. Installed

JP7 Shifts the gain of Channel 1 up or down by 14 dB. Installed

JP8 Connects trimmer VREFADJ to the VREF pin to change the gain slope. Installed

AD605

Rev. F | Page 19 of 24

R11

DNI

R12

DNI

00541-044

VGN1

+IN1 FBK1

OUT1

VREF

–IN1

GND1

GND2

+IN2

–IN2

VGN2 VOCM

OUT2

VPOS

FBK2

+5V

AD605

C11

0.1µF

10µF

10V

NOTES

1. PARTS IN GRAY ARE NOT INSTALLED.

0.1µF

69.8Ω

VGA1_NEG

VGA1_POS

69.8Ω

JP2

0.1µF

INM1

INP1

0.1µF

69.8Ω

VGA2_NEG

VGA2_POS

69.8Ω

JP3

0.1µF

INM2

INP2

DNI

CH1_GN

GN1

CH2_GN

GN2

1nF

JP1

+5V

1nF

JP4

+5V

10kΩ

GN1

ADJ

10kΩ

GN2

ADJ

C12

0.1µF

OUT1 R13

49.9Ω

C13

0.1µF

OUT1

C14

0.1µF

R14

10kΩ

+5V

JP8

REF

ADJ

VREF

JP7

OUT2

R10

49.9Ω

C10

0.1µF J7

OUT2

0.1µF

10kΩ

+5V

JP5

VOCM

JP6

VOCM

ADJ

GND1

GND2 GND3 GND4

+5V

DNI

Figure 43. Schematic Diagram of the AD605-EVALZ Evaluation Board

00541-045

FUNCTION GENERATOR

VGA OUTPUT

(TO SCOPE)

SINGLE-ENDED

INPUT

POWER SUPPLY

GND

OSCILLOSCOPE

+5 V

Figure 44. Typical Test Configuration of the AD605-EVALZ

AD605

Rev. F | Page 20 of 24

00541-046

Figure 45. AD605-EVALZ Assembly

00541-047

Figure 46. AD605-EVALZ Primary Side Copper

00541-048

Figure 47. AD605-EVALZ Secondary Side Copper

0541-049

Figure 48. AD605-EVALZ Internal Ground Plane

0541-050

Figure 49. AD605-EVALZ Internal Power Plane

00541-051

Figure 50. AD605-EVALZ Primary Side Silkscreen

AD605

Rev. F | Page 21 of 24

OUTLINE DIMENSIONS

CONTROLLING DIMENSIONS ARE IN INCHES; MILLIMETER DIMENSIONS

(IN PARENTHESES) ARE ROUNDED-OFF INCH EQUIVALENTS FOR

REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.

CORNER LEADS MAY BE CONFIGURED AS WHOLE OR HALF LEADS.

COMPLIANT TO JEDEC STANDARDS MS-001-AB

073106-B

0.022 (0.56)

0.018 (0.46)

0.014 (0.36)

0.150 (3.81)

0.130 (3.30)

0.115 (2.92)

0.070 (1.78)

0.060 (1.52)

0.045 (1.14)

0.100 (2.54)

BSC

0.800 (20.32)

0.790 (20.07)

0.780 (19.81)

0.210 (5.33)

MAX

SEATING

PLANE

0.015

(0.38)

MIN

0.005 (0.13)

MIN

0.280 (7.11)

0.250 (6.35)

0.240 (6.10)

0.060 (1.52)

MAX

0.430 (10.92)

MAX

0.014 (0.36)

0.010 (0.25)

0.008 (0.20)

0.325 (8.26)

0.310 (7.87)

0.300 (7.62)

0.015 (0.38)

GAUGE

PLANE

0.195 (4.95)

0.130 (3.30)

0.115 (2.92)

Figure 51. 16-Lead Plastic Dual In-Line Package [PDIP]

(N-16)

Dimensions shown in inches and (millimeters)

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.

COMPLIANT TO JEDEC STANDARDS MS-012-AC

10.00 (0.3937)

9.80 (0.3858)

16 9

6.20 (0.2441)

5.80 (0.2283)

4.00 (0.1575)

3.80 (0.1496)

1.27 (0.0500)

BSC

SEATING

PLANE

0.25 (0.0098)

0.10 (0.0039)

0.51 (0.0201)

0.31 (0.0122)

1.75 (0.0689)

1.35 (0.0531)

0.50 (0.0197)

0.25 (0.0098)

1.27 (0.0500)

0.40 (0.0157)

0.25 (0.0098)

0.17 (0.0067)

COPLANARITY

0.10

8°

0°

060606-A

45°

Figure 52. 16-Lead Standard Small Outline Package [SOIC_N]

Narrow Body

(R-16)

Dimensions shown in millimeters and (inches)

AD605

Rev. F | Page 22 of 24

ORDERING GUIDE

Model Temperature Range Package Description Package Option

AD605AN −40°C to +85°C 16-Lead PDIP N-16

AD605ANZ1

−40°C to +85°C 16-Lead PDIP N-16

AD605AR −40°C to +85°C 16-Lead SOIC_N R-16

AD605AR-REEL −40°C to +85°C 16-Lead SOIC_N, 13" Tape and Reel R-16

AD605AR-REEL7 −40°C to +85°C 16-Lead SOIC_N, 7" Tape and Reel R-16

AD605ARZ1

−40°C to +85°C 16-Lead SOIC_N R-16

AD605ARZ-RL1

−40°C to +85°C 16-Lead SOIC_N, 13" Tape and Reel R-16

AD605ARZ-R71

−40°C to +85°C 16-Lead SOIC_N, 7" Tape and Reel R-16

AD605BN −40°C to +85°C 16-Lead PDIP N-16

AD605BR −40°C to +85°C 16-Lead SOIC_N R-16

AD605BR-REEL −40°C to +85°C 16-Lead SOIC_N, 13" Tape and Reel R-16

AD605BR-REEL7 −40°C to +85°C 16-Lead SOIC_N, 7" Tape and Reel R-16

AD605BRZ1

−40°C to +85°C 16-Lead SOIC_N R-16

AD605BRZ-RL1

−40°C to +85°C 16-Lead SOIC_N, 13" Tape and Reel R-16

AD605BRZ-R71

−40°C to +85°C 16-Lead SOIC_N, 7" Tape and Reel R-16

AD605-EVALZ1

Evaluation Board

AD605ACHIPS DIE

1 Z = RoHS Compliant Part.

AD605

Rev. F | Page 23 of 24

NOTES

AD605

Rev. F | Page 24 of 24

NOTES

registered trademarks are the property of their respective owners.

D00541-0-6/08(F)