Datasheet AD8180AN, AD8180-EB, AD8182AR-REEL7, AD8182AR-REEL, AD8182AR Datasheet (Analog Devices)

750 MHz, 3.8 mA

1
2
3
4

8
7
6
5

AD8180

IN0

–V

S

OUT

ENABLE

SELECT

GND

IN1

+V

S

DECODER

+1

+1

1
2
3
4

14
13
12
11

AD8182

–V

S

OUT A

ENABLE A

SELECT A

5
6

7

10

9

8

SELECT B

OUT B
ENABLE B

DECODER

+1

+1

DECODER

+1

+1

IN0 A

GND

IN1 A

+V

S

IN1 B

GND

IN0 B

500mV

/DIV

5ns/DIV

a

FEATURES
Fully Buffered Inputs and Outputs
Fast Channel Switching: 10 ns
High Speed

> 750 MHz Bandwidth (–3 dB)
750 V/␮s Slew Rate

Fast Settling Time of 14 ns to 0.1%
Low Power: 3.8 mA (AD8180), 6.8 mA (AD8182)
Excellent Video Specifications (R

Gain Flatness of 0.1 dB Beyond 100 MHz

0.02% Differential Gain Error

0.02ⴗ Differential Phase Error
Low Glitch: < 35 mV
Low All-Hostile Crosstalk of –80 dB @ 5 MHz
High “OFF” Isolation of –90 dB @ 5 MHz
Low Cost
Fast Output Disable Feature for Connecting Multiple Devices

APPLICATIONS
Pixel Switching for “Picture-In-Picture”
Switching in LCD and Plasma Displays
Video Switchers and Routers

≥ 1 k⍀)

L

10 ns Switching Multiplexers

AD8180/AD8182*

FUNCTIONAL BLOCK DIAGRAM

Table I. Truth Table

PRODUCT DESCRIPTION

The AD8180 (single) and AD8182 (dual) are high speed 2-to-1
multiplexers. They offer –3 dB signal bandwidth greater than

750 MHz along with slew rate of 750 V/µs. With better than

80 dB of crosstalk and isolation, they are useful in many high
speed applications. The differential gain and differential phase

error of 0.02% and 0.02°, along with 0.1 dB flatness beyond

100 MHz make the AD8180 and AD8182 ideal for professional
video multiplexing. They offer 10 ns switching time making
them an excellent choice for pixel switching (picture-in-picture)

while consuming less than 3.8 mA (per 2:1 mux) on ±5 V sup-

ply voltages.

Both devices offer a high speed disable feature allowing the
output to be configured into a high impedance state. This al­lows multiple outputs to be connected together for cascading
stages while the “OFF” channels do not load the output bus.

They operate on voltage supplies of ±5 V and are offered in 8-

and 14-lead plastic DIP and SOIC packages.

*Protected under U.S. Patent Number 5,955,908.

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
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.

SELECT ENABLE OUTPUT

00 IN0
10 IN1
0 1 High Z
1 1 High Z

Figure 1. AD8180/AD8182 Switching Characteristics

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700 World Wide Web Site: http://www.analog.com
Fax: 781/326-8703 © Analog Devices, Inc., 2000

AD8180/AD8182–SPECIFICATIONS

(@ TA = +25ⴗC, VS = ⴞ5 V, RL = 2 k⍀ unless otherwise noted)

Parameter Conditions Min Typ Max Units

AD8180A/AD8182A

SWITCHING CHARACTERISTICS

Channel Switching Time

50% Logic to 10% Output Settling IN0 = +1 V, IN1 = –1 V; R
50% Logic to 90% Output Settling IN0 = +1 V, IN1 = –1 V; R
50% Logic to 99.9% Output Settling IN0 = +1 V, IN1 = –1 V; R
ENABLE to Channel ON Time

50% Logic to 90% Output Settling IN0 = +1 V, –1 V or IN1 = –1 V, +1 V; R
ENABLE to Channel OFF Time

50% Logic to 90% Output Settling IN0 = +1 V, –1 V or IN1 = –1 V, +1 V; R
Channel Switching Transient (Glitch)

1

2

2

3

Channel-to-Channel

L

L

SEL = 0 or 1

L

SEL = 0 or 1

All Inputs Are Grounded, R

= 1 kΩ 5ns
= 1 kΩ 10 ns
= 1 kΩ 14 ns

= 1 kΩ 10.5 ns

L

= 1 kΩ 11 ns

= 1 kΩ±25 /±35 mV

L

L

DIGITAL INPUTS

Logic “1” Voltage SEL and ENABLE Inputs 2.0 V
Logic “0” Voltage SEL and ENABLE Inputs 0.8 V
Logic “1” Input Current SEL, ENABLE = +4 V 10 200 nA
Logic “0” Input Current SEL, ENABLE = +0.4 V 2 3 µA

DYNAMIC PERFORMANCE

–3 dB Bandwidth (Small Signal)4AD8180R VIN = 50 mV rms, R

–3 dB Bandwidth (Small Signal)4AD8182R VIN = 50 mV rms, R

–3 dB Bandwidth (Large Signal) AD8180R VIN = 1 V rms, R

–3 dB Bandwidth (Large Si AD8182R VIN = 1 V rms, R

0.1 dB Bandwidth

0.1 dB Bandwidth

4, 5

4, 5

AD8180R VIN = 50 mV rms, R

VIN = 50 mV rms, R

AD8182R VIN = 50 mV rms, R

= 5 kΩ 750 930 MHz

L

= 5 kΩ 640 780 MHz

L

= 5 kΩ 120 150 MHz

L

= 5 kΩ 110 135 MHz

L

= 5 kΩ, RS = 0 Ω 100 MHz

L

= 1 kΩ–5 kΩ, RS = 150 Ω 210 MHz

L

= 1 kΩ–5 kΩ, RS = 125 Ω 210 MHz

L

Slew Rate 2 V Step 750 V/µs

Settling Time to 0.1% 2 V Step 14 ns

DISTORTION/NOISE PERFORMANCE

Differential Gain ƒ = 3.58 MHz, R
Differential Phase ƒ = 3.58 MHz, R
All Hostile Crosstalk

All Hostile Crosstalk

OFF Isolation

OFF Isolation

6

6

7

7

AD8180R ƒ = 5 MHz, R

ƒ = 30 MHz, R

AD8182R ƒ = 5 MHz, R

ƒ = 30 MHz, R
AD8180R ƒ = 5 MHz, R
AD8182R ƒ = 5 MHz, R

= 1 kΩ 0.02 0.04 %

L

= 1 kΩ 0.02 0.04 Degrees

L

= 1 kΩ –80 dB

L

= 1 kΩ –65 dB

L

= 1 kΩ –78 dB

L

= 1 kΩ –63 dB

L

= 30 Ω –89 dB

L

= 30 Ω –93 dB

L

Voltage Noise ƒ = 10 kHz–30 MHz 4.5 nV/√Hz

Total Harmonic Distortion ƒC = 10 MHz, VO = 2 V p-p, R

DC/TRANSFER CHARACTERISTICS

Voltage Gain

8

V

= ±1 V, RL = 2 kΩ 0.982 V/V

IN

V

= ±1 V, RL = 10 kΩ 0.986 0.993 V/V

IN

= 1 kΩ –78 dBc

L

Input Offset Voltage 112mV

T

MIN

to T

MAX

15 mV

Input Offset Voltage Matching Channel-to-Channel 0.5 4 mV

Input Offset Drift 11 µV/°C
Input Bias Current 15 µA

T

MIN

to T

MAX

7 µA

Input Bias Current Drift 12 nA/°C

INPUT CHARACTERISTICS

Input Resistance 1 2.2 MΩ

Input Capacitance Channel Enabled (R Package) 1.5 pF

Channel Disabled (R Package) 1.5 pF

Input Voltage Range ±3.3 V

OUTPUT CHARACTERISTICS

Output Voltage Swing R

= 500 Ω

L

9

±3.0 ±3.1 V

Short Circuit Current 30 mA

Output Resistance Enabled 27 Ω

Disabled 1 10 MΩ

Output Capacitance Disabled (R Package) 1.7 pF

POWER SUPPLY

Operating Range ±4 ±6V

Power Supply Rejection Ratio +PSRR +VS = +4.5 V to +5.5 V, –VS = –5 V 54 57 dB

Power Supply Rejection Ratio –PSRR –VS = –4.5 V to –5.5 V, +VS = +5 V 45 51 dB

Quiescent Current All Channels “ON” 3.8/6.8 4.5/8 mA

T

MIN

to T

MAX

4.75/8.5 mA
All Channels “OFF” 1.3/2 2/3 mA
T

MIN

to T

MAX

2/3 mA

AD8182, One Channel “ON” 4 mA

OPERATING TEMPERATURE RANGE –40 +85 °C

REV. B–2–

NOTES

WARNING!

ESD SENSITIVE DEVICE

AD8180/AD8182

1

ENABLE pin is grounded. IN0 = +1 V dc, IN1 = –1 V dc. SELECT input is driven with 0 V to +5 V pulse. Measure transition time from 50% of the SELECT input value
(+2.5 V) and 10% (or 90%) of the total output voltage transition from IN0 channel voltage (+1 V) to IN1 (–1 V), or vice versa.

2

ENABLE pin is driven with 0 V to +5 V pulse (with 3 ns edges). State of SELECT input determines which channel is activated (i.e., if SELECT = Logic 0, IN0 is selected). Set
IN0 = +1 V dc, IN1 = –1 V dc, and measure transition time from 50% of ENABLE pulse (+2.5 V) to 90% of the total output voltage change. In Figure 5, ∆t
time,

3

All inputs are grounded. SELECT input is driven with 0 V to +5 V pulse. The outputs are monitored. Speeding the edges of the SELECT pulse increases the glitch magnitude
due to coupling via the ground plane. Removing the SELECT input termination will lower glitch, as does increasing R

4

Decreasing RL lowers the bandwidth slightly. Increasing CL lowers the bandwidth considerably (see Figure 19).

5

A resistor (RS) placed in series with the mux inputs serves to optimize 0.1 dB flatness, but is not required. Increasing output capacitance will increase peaking and reduce band­width (see Figure 20.)

6

Select input which is not being driven (i.e., if SELECT is Logic 1, input activated is IN1); drive all other inputs with V
R

7

Mux is disabled (i.e., ENABLE = Logic 1) and all inputs are driven simultaneously with VIN = 0.446 V rms. Output is monitored at ƒ = 5 and 30 MHz. RL = 30 Ω to simulate
R
ance determines the crosstalk.

8

Voltage gain decreases for lower values of R
(i.e., the voltage gain is approximately 0.97 V/V (3% gain error) for R

9

Larger values of RL provide wider output voltage swings, as well as better gain accuracy. See Note 8.

Specifications subject to change without notice.

ABSOLUTE MAXIMUM RATINGS

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

Internal Power Dissipation

is the enable time.

∆tON

.

L

= 0.707 V rms and monitor output at ƒ = 5 and 30 MHz.

= 1 kΩ (see Figure 13).

L

of one enabled mux within a system (see Figure 14). In this mode the output impedance is very high (typ 10 MΩ), and the signal couples across the package; the load imped-

ON

. The resistive divider formed by the mux enabled output resistance (27 Ω) and R

L

1

2

AD8180 8-Lead Plastic DIP (N) . . . . . . . . . . . . . . . . 1.3 Watts

AD8180 8-Lead Small Outline (R) . . . . . . . . . . . . . . 0.9 Watts

= 1 kΩ).

L

While the AD8180 and AD8182 are internally short circuit
protected, this may not be sufficient to guarantee that the maxi-

mum junction temperature (+150°C) is not exceeded under all

conditions. To ensure proper operation, it is necessary to observe
the maximum power derating curves shown in Figures 2 and 3.

IN

causes a gain which decreases as RL decreases

L

AD8182 14-Lead Plastic DIP (N) . . . . . . . . . . . . . . . 1.6 Watts

AD8182 14-Lead Small Outline (R) . . . . . . . . . . . . . 1.0 Watts

Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±V

Output Short Circuit Duration . . . . . Observe Power Derating Curves

Storage Temperature Range

S

2.0
8-LEAD PLASTIC DIP PACKAGE

TJ = +1508C

1.5

N and R Package . . . . . . . . . . . . . . . . . . . . . . –65°C to +125°C

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

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: 8-Lead Plastic DIP Package: θJA = 90°C/W;

8-Lead SOIC Package: θ
14-Lead SOIC Package: θJA = 120°C/W, where P

= 155°C/W; 14-Lead Plastic Package: θJA = 75°C/W;

JA

= (TJ–T

D

)/θ

.

A

JA

ORDERING GUIDE

Temperature Package Package

Model Range Description Option

1.0

0.5

MAXIMUM POWER DISSIPATION – Watts

0
–50 90–40 –30 –20 –10 0 10 20 30 50 60 70 8040

8-LEAD SOIC PACKAGE

AMBIENT TEMPERATURE – 8C

Figure 2. AD8180 Maximum Power Dissipation vs.
Temperature

AD8180AN –40°C to +85°C 8-Lead Plastic DIP N-8
AD8180AR –40°C to +85°C 8-Lead SOIC SO-8
AD8180AR-REEL –40°C to +85°C 13" Reel SOIC SO-8
AD8180AR-REEL7 –40°C to +85°C 7" Reel SOIC SO-8
AD8182AN –40°C to +85°C 14-Lead Plastic DIP N-14
AD8182AR –40°C to +85°C 14-Lead Narrow SOIC R-14
AD8182AR-REEL –40°C to +85°C 13" Reel SOIC R-14

2.5

2.0

TJ = +1508C

14-LEAD
PLASTIC DIP PACKAGE

AD8182AR-REEL7 –40°C to +85°C 7" Reel SOIC R-14

AD8180-EB Evaluation Board
AD8182-EB Evaluation Board

1.5

is the disable

OFF

MAXIMUM POWER DISSIPATION

The maximum power that can be safely dissipated by the

14-LEAD SOIC

1.0

AD8180 and AD8182 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. Exceeding

this limit temporarily 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

MAXIMUM POWER DISSIPATION – Watts

0.5

–50 90–40

–30 –20 –10 0 10 20 30 40 50 60 80

AMBIENT TEMPERATURE – 8C

Figure 3. AD8182 Maximum Power Dissipation vs.
Temperature

extended period can result in device failure.

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 AD8180/AD8182 feature 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.

REV. B

–3–

70

AD8180/AD8182–Typical Performance Curves

–7

0

–1

–2

–3

–4

–5

–6

VIN = 50mV rms
RL = 5kV
RS = 0V

1

NORMALIZED OUTPUT – dB

8180R

8182R

1M 10M 100M 1G

FREQUENCY – Hz

500mV

/DIV

5ns/DIV

Figure 4. Channel Switching Characteristics

DUT OUT

250mV

/DIV

10ns/DIV

Figure 5. Enable and Disable Switching Characteristics

50mV

/DIV

25ns/DIV

Figure 6. Channel Switching Transient (Glitch)

–4–

Figure 7. Small Signal Frequency Response

VIN = 50mV rms
R

= 5kV

L

= 0V

R

S

1.0

0.8

0.6

0.4

0.2

0.0

NORMALIZED FLATNESS – dB

–0.2

–0.4

1M 10M 100M 1G

FREQUENCY – Hz

8180R

8182R

Figure 8. Gain Flatness vs. Frequency

3

RL = 1kV

0

–3

–6
–9

–12
–15
–18

INPUT/OUTPUT LEVEL – dBV

–21
–24
–27

1M 1G10M 100M

VIN = 1.0V rms

VIN = 0.5V rms

VIN = 0.25V rms

VIN = 125mV rms

VIN = 62.5mV rms

FREQUENCY – Hz

Figure 9. Large Signal Frequency Response

REV. B

FREQUENCY – Hz

0.1M 1G1M 10M 100M

–10

–20

–110

–30

–40
–50

–60
–70
–80

–90

–100

CROSSTALK – dB

VIN = 0.707V rms
R

L

= 1kV

AD8182R

AD8180R

OUT A

OUT B

50V

V

IN

50V

1

3

5

7

50V

AD8182

1kV

1kV

OFF ISOLATION – dB

FREQUENCY – Hz

0.03M 1G0.1M 1M 10M 100M

–10

–20

–110

–30

–40
–50

–60
–70
–80

–90

–100

ALL INPUTS = 0.446V rms
R

L

= 30V

8180R OR
8182R

ENABLE A = LOGIC 1
ENABLE B = LOGIC 0

50V

V

IN

50V

8182R

ENABLE A/B = LOGIC 1

AD8182

OUT A

OUT B

30V

30V

FREQUENCY – Hz

100

10

1

10 1M100 1k 10k 100k 10M

VOLTAGE NOISE – nV/ Hz

30M

50mV

/DIV

AD8180/AD8182

5ns/DIV

Figure 10. Small Signal Transient Response

500mV

/DIV

5ns/DIV

Figure 11. Large Signal Transient Response

0.020

0.015

0.010

0.005

0.000
–0.005
–0.010

DIFF GAIN – %

–0.015
–0.020

0.02

0.01

0.00
–0.01
–0.02

DIFF PHASE – Degrees

1234 567891011

1234 567891011

IRE

IRE

RL = 1kV
NTSC

Figure 13. All-Hostile Crosstalk vs. Frequency

Figure 14. “OFF” Isolation vs. Frequency

REV. B

Figure 12. Differential Gain and Phase Error

Figure 15. Voltage Noise vs. Frequency

–5–

AD8180/AD8182–Typical Performance Curves

NORMALIZED OUTPUT – dB

+1
0

–9

–1

–2
–3

–4
–5
–6

–7
–8

–0.4

+0.1

0

–0.1

–0.2
–0.3

NORMALIZED FLATNESS – dB

VIN = 500mV rms
R

L

= 5kV

CL =
0pF

CL =

10pF

CL =

33pF

CL = 100pF

CL = 100pF

CL = 33pF

10M 100M 1G4M 40M 400M

FREQUENCY – Hz

1M

NORMALIZED OUTPUT – dB

+1
0

–9

–1

–2
–3

–4
–5

–6
–7
–8

–0.4

0.6

0.4

0.2
0

–0.2

NORMALIZED FLATNESS – dB

VIN = 50mV rms
R

L

= 5kV

RS = 0V

RS = 75V

0.8

1.0

RS = 150V

RS = 0V

RS = 75V

RS = 150V

10M 100M40M

FREQUENCY – Hz

400M 1G4M1M

INPUT VOLTAGE – Volts

5

–1

–5

–5 5–4–3–2–101234

4

0

–2

–4

2
1

–3

3

OUTPUT VOLTAGE – Volts

–25

V

= 2V p-p

OUT

R

= 1kV

L

–35

–45

–55

–65

–75

HARMONIC DISTORTION – dBc

–85

–95

100k

1M 10M

2ND HARMONIC

FREQUENCY – Hz

3RD HARMONIC

100M

150M

200M

Figure 16. Harmonic Distortion vs. Frequency

31.6M

3.16M

ZIN (ENABLED)

316k

31.6k

3.16k

316

31.6

DISABLED OUTPUT AND INPUT IMPEDANCE – V

1k 100M10k 100k 1M 10M

Z

(DISABLED)

OUT

Z

OUT

FREQUENCY – Hz

(ENABLED)

1G

120

100

80

60

40

20

0

Figure 17. Disabled Output and Input Impedance vs.
Frequency

Figure 19. Frequency Response vs. Capacitive Load

ENABLED OUTPUT IMPEDANCE – V

Figure 20. Frequency Response vs. Input Series Resistance

0

–10

–20

–30

–40

PSRR – dB

–50

–60

–70

0.03 5000.1 1 10 100

Figure 18. Power Supply Rejection vs. Frequency

+PSRR

FREQUENCY – MHz

–PSRR

Figure 21. Output Voltage vs. Input Voltage, RL = 1 k

–6–

Ω

REV. B

AD8180/AD8182

THEORY OF OPERATION

The AD8180 and AD8182 video multiplexers are designed for
fast-switching (10 ns) and wide bandwidth (> 750 MHz). This
performance is attained with low power dissipation (3.8 mA per
active channel) through the use of proprietary circuit techniques
and a dielectrically-isolated complementary bipolar process.
These devices have a fast disable function that allows the out­puts of several muxes to be wired in parallel to form a larger mux
with little degradation in switching time. The low disabled output
capacitance (1.7 pF) of these muxes helps to preserve the system
bandwidth in larger matrices. Unlike earlier CMOS switches,
the switched open-loop buffer architecture of the AD8180 and
AD8182 provides a unidirectional signal path with minimal switch­ing glitches and constant, low input capacitance. Since the input
impedance of these muxes is nearly independent of the load imped­ance and the state of the mux, the frequency response of the ON
channels in a large switch matrix is not affected by fanout.

Figure 22 shows a block diagram and simplified schematic of the
AD8180, which contains two switched buffers (S0 and S1) that
share a common output. The decoder logic translates TTL­compatible logic inputs (SELECT and ENABLE) to internal,
differential ECL levels for fast, low-glitch switching. The SELECT
input determines which of the two buffers is enabled, unless the
ENABLE input is HIGH, in which case both buffers are disabled
and the output is switched to a high impedance state.

AD8180

IN0

GND

IN1

+V

I1

1

Q1

2

S0

I2

3

Q2

4

S

S1

Q3

I3

DECODER

Q4

I4

Q5

Q7

Q6

Q8

8

7

6

5

SELECT

ENABLE

OUT

–V

S

Figure 22. Block Diagram and Simplified Schematic of the
AD8180 Multiplexer

Each open-loop buffer is implemented as a complementary
emitter follower that provides high input impedance, symmetric
slew rate and load drive, and high output-to-input isolation due to

2

current gain. The selected buffer is biased ON by fast

its β

switched current sources that allow the buffer to turn on quickly.
Dedicated flatness circuits, combined with the open-loop architec­ture of the AD8180 and AD8182, keep peaking low (typically
< 1 dB) when driving high capacitive loads, without the need for
external series resistors at the input or output. If better flatness
response is desired, an input series resistance (R

) may be used

S

(refer to Figure 20), although this will increase crosstalk. The dc
gain of the AD8180 and AD8182 is almost independent of load

for R

> 10 kΩ. For heavier loads, the dc gain is approximately

L

that of the voltage divider formed by the output impedance of

the mux (typically 27 Ω) and R

.

L

High speed disable clamp circuits at the bases of Q5–Q8 (not
shown) allow the buffers to turn off quickly and cleanly without
dissipating much power once off. Moreover, these clamps shunt
displacement currents flowing through the junction capacitances
of Q1–Q4 away from the bases of Q5–Q8 and to ac ground
through low impedances. The two-pole high pass frequency
response of the T switch formed by these clamps is a significant
improvement over the one-pole high pass response of a simple
series CMOS switch. As a result, board and package parasitics,
especially stray capacitance between inputs and outputs may
limit the achievable crosstalk and off isolation.

LAYOUT CONSIDERATIONS:

Realizing the high speed performance attainable with the
AD8180 and AD8182 requires careful attention to board layout
and component selection. Proper RF design techniques and low
parasitic component selection are mandatory.

Wire wrap boards, prototype boards, and sockets are not recom­mended because of their high parasitic inductance and capaci­tance. Instead, surface-mount components should be soldered
directly to a printed circuit board (PCB). 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 input and
output pins to reduce stray capacitance.

Chip capacitors should be used for supply bypassing. One end
of the capacitor should be connected to the ground plane and
the other within 1/4 inch of each power pin. An additional large

(4.7 µF–10 µF) tantalum capacitor should be connected in

parallel with each of the smaller capacitors for low impedance
supply bypassing over a broad range of frequencies.

Signal traces should be as short as possible. Stripline or micros­trip techniques should be used for long signal traces (longer
than about 1 inch). These should be designed with a character-

istic impedance of 50 Ω or 75 Ω and be properly terminated at

the end using surface mount components.

Careful layout is imperative to minimize crosstalk. Guards
(ground or supply traces) must be run between all signal traces
to limit direct capacitive coupling. Input and output signal lines
should fan out away from the mux as much as possible. If mul­tiple signal layers are available, a buried stripline structure hav­ing ground plane above, below, and between signal traces will
have the best crosstalk performance.

Return currents flowing through termination resistors can also
increase crosstalk if these currents flow in sections of the finite­impedance ground circuit that is shared between more than one
input or output. Minimizing the inductance and resistance of the
ground plane can reduce this effect, but further care should be
taken in positioning the terminations. Terminating cables directly
at the connectors will minimize the return current flowing on the
board, but the signal trace between the connector and the mux will
look like an open stub and will degrade the frequency response.
Moving the termination resistors close to the input pins will im­prove the frequency response, but the terminations from neigh­boring inputs should not have a common ground return.

REV. B

–7–

AD8180/AD8182

APPLICATIONS
Multiplexing two RGB Video Sources

A common video application requires two RGB sources to be
multiplexed together before the selected signal is applied to a
monitor. Typically one source would be the PC’s normal output,
the second source might be a specialized source such as MPEG
video. Figure 23 shows how such a circuit could be realized
using the AD8180 and AD8182 and three current feedback op
amps. The video inputs to the multiplexers are terminated with

75 Ω resistors. This has the effect of halving the signal amplitude

of the applied signals.

Because all three multiplexers are permanently active, the
ENABLE pins are tied permanently low. The three SELECT
pins are tied together and this signal is used to select the source.

In order to drive a 75 Ω back terminated load (R

= 150 Ω), the

L

multiplexer outputs are buffered using the AD8001 current feed­back op amp. A gain of two compensates for the signal halving by
the AD8001 output back termination resistor so that the system
has an overall gain of unity.

If lower speed and crosstalk can be tolerated, either of the triple
op amps, AD8013 or AD8073, can replace the three AD8001 op
amps in the above circuit. Because both devices have bandwidths
in the 100 MHz to 140 MHz range at a gain of +2, these ampli­fiers will dominate the frequency response of the circuit.

MPEG

RGB

RGB

COMPUTER

GRAPHICS

75V

75V

75V

75V

75V

+V

75V

1

+1

2

DECODER

3

+1

+V

S

0.1mF
+

10mF

0.1mF

S

+ +

10mF

AD8180

4

1

+1

2

DECODER

3

+1

AD8182

4
5

+1

DECODER

6
7

+1

8

ENABLE

7
6
5

14

ENABLE A

13
12
11
10

9
8

0.1mF

10mF

10mF

With no signal present, the total quiescent current of the cir-

cuit in Figure 23 is 25.6 mA (3.8 mA + 6.8 mA + 3 × 5 mA), or

about 8.5 mA per channel. If either the AD8013 or AD8073
are used, the quiescent current will decrease to about 6.5 mA
per channel.

To reduce power consumption further, three AD8011 single
op amps can be used. With a quiescent current of 1 mA, this
will reduce the per channel quiescent current to about 4.5 mA.

Table II. Amplifier Options for RGB Multiplexer

Op Amp Comments

AD8001 Highest Bandwidth, 440 MHz (G = +2), I

= 5 mA

SY

AD8011 Lower Power Consumption, Bandwidth (G = +2) =

210 MHz, I

= 1 mA

SY

AD8013 Triple Op Amp, Bandwidth (G = +2) = 140 MHz,

= 3.4 mA

I

SY

AD8073 Lower Power Triple Op Amp, Bandwidth (G = +2) =

100 MHz, ISY = 3.5 mA

+V

AD8001

–V

+V

AD8001

–V

+V

AD8001

681V

S

S

681V

S

S

681V

S

10mF

+

0.1mF

0.1mF

10mF

10mF

+

0.1mF

0.1mF

10mF

10mF

+

0.1mF

0.1mF

75V

+

R

75V

G

MONITOR

B

+

75V

+

0.1mF

ENABLE B

R

TERM

681V

–V

S

–V

681V

S

681V

SELECT

–V

Figure 23. Multiplexing Two Component Video Sources

–8–

10mF

+

S

REV. B

AD8180/AD8182

Picture-in-Picture or Pixel Switching

Many high end display systems require simultaneous display of
two video pictures (from two different sources) on one screen.
Video conferencing is one such example. In this case the remote
site might be displayed as the main picture with a picture of the
local site “inset” for monitoring purposes. The circuit in Fig­ure 23 could also be used to implement this “picture-in-picture”
application.

Implementing a picture-in-picture algorithm is difficult for
several reasons. Both sources are being displayed simultaneously
(i.e., during the same frame), both sources are in real time, and
both must be synchronized. Figure 24 shows the raster scan­ning that takes place in all monitors. During every horizontal
scan that includes part of the inset, the source must be switched
twice (i.e., from main to inset and from inset to main). To avoid
screen artifacts, it is critical that switching is clean and fast. The
AD8180 and AD8182, in the above application, switch and
settle to 0.1% accuracy in 14 ns. We quadratically add this
value to the 10 ns settling time of the AD8001, and get an over­all settling time of 17.2 ns. This yields a sharp, artifact-free
border between the inset and the main video.

INSET VIDEO

MULTIPLEXER MUST SWITCH

MAIN VIDEO

CLEANLY ON EACH CROSSING

Figure 24. “Picture-in-Picture,” Pixel Switching

Color Document Scanner

Figure 25 shows a block diagram of a Color Document Scan­ner. Charge Coupled Devices (CCDs) find widespread use in
scanner applications. A monochrome CCD delivers a serial
stream of voltage levels, each level being proportional to the
light shining on that cell. In the case of the color image scanner
shown, there are three output streams, representing red, green
and blue. Interlaced with the stream of voltage levels is a voltage
representing the reset level (or black level) of each cell. A Corre­lated Double Sampler (CDS) subtracts these two voltages from
each other in order to eliminate the relatively large offsets which
are common with CCDs.

CONTROL AND TIMING

EN B

EN A

SEL B

R

C

C

D

CDS

G

CDS

B

REFERENCE

4:1 MUX TRUTH TABLE

SEL A, SEL B

0
0
1
1

CDS

SEL A

IN0 A

IN1 A

AD8182

IN1 B

IN0 B

ENA, ENB

0
1
0
1

OUT A

OUT B

OUTA, OUTB

IN0A
IN0B
IN1A
IN1B

100V

AD876 8/10-BIT

20MSPS

A/D

Figure 25. Color Document Scanner

The next step in the data acquisition process involves digitizing
the three signal streams. Assuming that the analog to digital
converter chosen has a fast enough sample rate, multiplexing
the three streams into a single ADC is generally more eco­nomic than using one ADC per channel. In the example
shown, we use the two 2-to-1 multiplexers in the AD8182 to
create a 4-to-1 multiplexer. The enable control pins on the
multiplexers allow the outputs to be wired directly together.

Because of its high bandwidth, the AD8182 is capable of driv­ing the switched capacitor input stage of the AD876 without
additional buffering. In addition to having the required the
bandwidth, it is necessary to consider the settling time of the
multiplexer. In this case, the ADC has a sample rate of 20 MHz
which corresponds to a sampling period of 50 ns. Typically,
one phase of the sampling clock is used for conversion (i.e., all
levels are held steady) and the other phase is used for switch­ing and settling to the next channel. Assuming a 50% duty cycle,
the signal chain must settle within 25 ns. With a settling time to

0.1% of 14 ns, the multiplexer easily satisfies this criterion.

In the example shown, the fourth (spare) channel of the
AD8182 is used to measure a reference voltage. This voltage
would probably be measured less frequently than the R, G and
B signals. Multiplexing a reference voltage offers the advantage
that any temperature drift effects caused by the multiplexer
will equally impact the reference voltage and the to-be­measured signals. If the fourth channel is unused, it is good
design practice to tie this input to ground.

REV. B

–9–

AD8180/AD8182

EVALUATION BOARD

Evaluation boards for the AD8180R and AD8182R are available
which have been carefully laid out and tested to demonstrate the
specified high speed performance of the devices. Figure 26 and
Figure 27 show the schematics of the AD8180 and AD8182
evaluation boards respectively. For ordering information, please
refer to the Ordering Guide.

Because the footprint of the AD8180 fits directly on to that of
the AD8182, one board layout can be used for both devices. In the
case of the AD8180, only the top half of the board is populated.

Figure 28 shows the silkscreen of the component side and Fig­ure 30 shows the silkscreen of the solder side. Figures 29 and 31
show the layout of the component side and solder side respectively.

ENABLE

R8

SELECT

49.9V

R9

49.9V

IN0

R1

49.9V

IN1

R10

+V

49.9V

S

UNLESS OTHERWISE NOTED, CONNECTORS ARE SMA TYPE

C1

0.1mF

C4

10mF

1

+1

2

DECODER

3

+1

AD8180R

4

+

Figure 26. AD8180R Evaluation Board

The evaluation board is provided with 49.9 Ω termination resis-

tors on all inputs. This is to allow the performance to be evalu-

ated at very high frequencies where 50 Ω termination is most

popular. To use the evaluation board in video applications, the

termination resistors should be replaced with 75 Ω resistors.
The multiplexer outputs are loaded with 4.99 kΩ resistors. In

order to avoid large gain errors, these load resistors should be

greater than or equal to 1 kΩ. For connection to external instru-

ments, oscilloscope scope probe adapters are provided. This
allows direct connection of FET probes to the board. For verifi­cation of data sheet specifications, use of FET probes with a
bandwidth > 1 GHz is recommended because of their low input
capacitance. The probe adapters used on the board have the
same footprint as SMA, SMB and SMC type connectors allow­ing easy replacement if necessary.

8
7
6

C2

0.1mF

C3

10mF

–V

+

5

OUT

(SCOPE PROBE

ADAPTER)

R7

4.99kV

S

ENABLE A

SELECT A

IN0 A

IN1 A

IN1 B

IN0 B

SELECT B

ENABLE B

R8

49.9V

R9

49.9V

1

+1

DECODER

2

C1

0.1mF

10mF

R3

49.9V

R5

49.9V

3

+1

AD8182R

4

+

+1

5

C4

6

DECODER

7

+1

R4

49.9V

UNLESS OTHERWISE NOTED, CONNECTORS ARE SMA TYPE

14
13

0.1mF

12
11
10

10mF

9
8

4.99kV

+V

R1

49.9V

R10

49.9V

S

R2

49.9V

Figure 27. AD8182R Evaluation Board

C2

–V

+

C3

R6

OUTA

(SCOPE PROBE

ADAPTER)

R7

4.99kV

S

OUTB

(SCOPE PROBE

ADAPTER)

–10–

REV. B

AD8180/AD8182

ANALOG

DEVICES

IN0A

J2

IN1A

V+

J3

IN1B

IN0B

R10

C1

R2

BOARD

R1

R3

J4

AD8180/82

J1

EVALUATION

J10

J9

SEL A

EN A

J8

R9

8

R

U1

C2

R5

R4

SEL B

J5

A

V–

B

J7

EN B

J6

R7

C3

6

R

C4

Figure 28. Component Side Silkscreen

Figure 29. Board Layout (Component Side)

NOTES

1. AD8180R/AD8182R Evaluation Board inputs are configured

with 50 Ω impedance striplines. This FR4 board type has the

following stripline dimensions: 60-mil width, 12-mil gap
between center conductor and outside ground plane “is­lands,” and 62-mil board thickness.

2. Several types of SMA connectors can be mounted on this
board: the side-mount type, which can be easily installed at
the edges of the board, and the top-mount type, which is
placed on top. When using the top-mount SMA connector, it
is recommended that the stripline on the outside 1/8" of the
board edge be removed with an X-Acto blade as this unused
stripline acts as an open stub, which could degrade the small­signal frequency response of the mux.

Figure 30. Solder Side Silkscreen

Figure 31. Board Layout (Solder Side)

3. Input termination resistor placement on the evaluation board
is critical to reducing crosstalk. Each termination resistor is
oriented so that ground return currents flow counterclock­wise to a ground plane “island.” Although the direction of
this ground current flow is arbitrary, it is important that no
two input or output termination resistors share a connection
to the same ground “island.”

REV. B

–11–

AD8180/AD8182

14

17

8

0.795 (20.19)

0.725 (18.42)

0.280 (7.11)

0.240 (6.10)

PIN 1

0.325 (8.25)

0.300 (7.62)

0.015 (0.381)

0.008 (0.204)

0.195 (4.95)

0.115 (2.93)

SEATING
PLANE

0.022 (0.558)

0.014 (0.356)

0.060 (1.52)

0.015 (0.38)

0.210 (5.33)
MAX

0.130
(3.30)
MIN

0.070 (1.77)

0.045 (1.15)

0.100
(2.54)

BSC

0.160 (4.06)

0.115 (2.93)

14 8

71

0.3444 (8.75)

0.3367 (8.55)

0.2440 (6.20)

0.2284 (5.80)

0.1574 (4.00)

0.1497 (3.80)

PIN 1

SEATING

PLANE

0.0098 (0.25)

0.0040 (0.10)

0.0192 (0.49)

0.0138 (0.35)

0.0688 (1.75)

0.0532 (1.35)

0.0500
(1.27)

BSC

0.0099 (0.25)

0.0075 (0.19)

0.0500 (1.27)

0.0160 (0.41)

8°
0°

0.0196 (0.50)

0.0099 (0.25)

x 45°

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

0.210 (5.33)
MAX

0.160 (4.06)

0.115 (2.93)

0.022 (0.558)

0.014 (0.356)

0.1574 (4.00)

0.1497 (3.80)

0.0098 (0.25)

0.0040 (0.10)

8-Lead Plastic DIP

0.430 (10.92)

0.348 (8.84)

8

5

14

PIN 1

0.100

0.070 (1.77)

(2.54)

0.045 (1.15)

BSC

8-Lead Plastic SOIC

0.1968 (5.00)

0.1890 (4.80)

8

5

41

PIN 1

0.0688 (1.75)

0.0532 (1.35)

(N-8)

0.280 (7.11)

0.240 (6.10)

0.060 (1.52)

0.015 (0.38)

0.130
(3.30)
MIN

SEATING
PLANE

(SO-8)

0.2440 (6.20)

0.2284 (5.80)

0.325 (8.25)

0.300 (7.62)

0.015 (0.381)

0.008 (0.204)

0.0196 (0.50)

0.0099 (0.25)

0.195 (4.95)

0.115 (2.93)

x 45°

14-Lead Plastic DIP

(N-14)

C2182a–0–1/00 (rev. B)

14-Lead SOIC

(R-14)

0.0500

SEATING

PLANE

(1.27)

BSC

0.0192 (0.49)

0.0138 (0.35)

0.0098 (0.25)

0.0075 (0.19)

8°
0°

0.0500 (1.27)

0.0160 (0.41)

–12–

–12–

PRINTED IN U.S.A.

REV. B