MAX4120ESD-T中文资料

General Description

The single MAX4112/MAX4113, dual MAX4117/MAX4118, and quad MAX4119/MAX4120 current feed-back amplifiers combine high-speed performance with low-power operation. The MAX4112/MAX4117/MAX4119 are optimized for closed-loop gains of 2V/V or greater, while the MAX4113/MAX4118/MAX4120 are optimized for gains of 8V/V or greater.

The MAX4112/MAX4117/MAX4119 and the MAX4113/MAX4118/MAX4120 require only 5mA of supply current per channel. The MAX4113/MAX4118/MAX4120 deliver 0.1dB gain flatness up to 115MHz. The MAX4112/MAX4117 have -3dB bandwidths of 400MHz (A V > 2V/V)and the MAX4118/MAX4120 have -3dB bandwidths of 300MHz (A V > 8V/V). Their high slew rates of up to 1800V/μs provide exceptional full-power bandwidths up to 280MHz, making these amplifiers ideal for high-perfor-mance pulse and RGB video applications.

These high-speed op amps have a wide output voltage swing of ±3.5V into 100?and a high current-drive capability of 80mA.

Applications

Broadcast and High-Definition TV Systems RGB Video Pulse/RF Amplifier

Ultrasound/Medical Imaging Active Filters

High-Speed ADC Buffers Professional Cameras High-Definition Surveillance

Features

?400MHz -3dB Bandwidth (MAX4112/MAX4117)270MHz -3dB Bandwidth (MAX4113/MAX4119)300MHz -3dB Bandwidth (MAX4118/MAX4120)?0.1dB Gain Flatness to 115MHz (MAX4113/MAX4118/MAX4120)? 1200V/μs Slew Rate

(MAX4112/MAX4117/MAX4119)1800V/μs Slew Rate

(MAX4113/MAX4118/MAX4120)

?280MHz Full-Power Bandwidth (V OUT = 2V P-P , MAX4112/MAX4117)240MHz Full-Power Bandwidth

(V OUT = 2V P-P , MAX4113/MAX4118/MAX4120)?High Output Drive: 80mA

?Low Power: 5mA Supply Current per Channel

MAX4112/MAX4113/MAX4117–MAX4120

Current Feedback Amplifiers

________________________________________________________________Maxim Integrated Products

1

Ordering Information continued at end of data sheet.*Contact factory for μMAX ?package availability.

μMAX is a registered trademark of Maxim Integrated Products, Inc.

__________________________________________________________Pin Configurations

For pricing, delivery, and ordering information,please contact Maxim/Dallas Direct!at 1-888-629-4642, or visit Maxim’s website at https://www.360docs.net/doc/4218754236.html,.

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers 2_______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

ELECTRICAL CHARACTERISTICS

(V CC = +5V, V EE = -5V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.) (Note 1)

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.

Power-Supply Voltage (V CC to V EE ).......................................12V Input Voltage (IN_+, IN_-)...................(V CC + 0.3V) to (V EE - 0.3V)IN_ _ Current (Note 1)......................................................±10mA Short-Circuit Duration (V OUT to GND)

V IN < 1.5V ...............................................................Continuous V IN > 1.5V..........................................................................0sec Continuous Power Dissipation (T A = +70°C)

8-Pin SO (derate 5.88mW/°C above +70°C).................471mW

8-Pin μMAX (derate 4.10mW/°C above +70°C)............330mW 14-Pin SO (derate 8.33mW/°C above +70°C)...............667mW 16-Pin QSOP (derate 9.52mW/°C above +70°C)..........762mW Operating Temperature Range

MAX41_ _E_ _...................................................-40°C to +85°C Storage Temperature Range.............................-65°C to +160°C Lead Temperature (soldering, 10s).................................+300°C

ELECTRICAL CHARACTERISTICS (continued)

(V CC = +5V, V EE = -5V, T A = T MIN to T MAX , unless otherwise noted. Typical values are at T A = +25°C.) (Note 1)

MAX4112/MAX4113/MAX4117–MAX4120

Single/Dual/Quad, 400MHz, Low-Power,

Current Feedback Amplifiers

_______________________________________________________________________________________3

Note 1:The MAX4112/MAX4113/MAX4117–MAX4120 are designed to operate in a closed-loop configuration in which the IN-pin is

driven by the OUT pin through an external feedback network. If an external voltage source is connected to IN-, current into or out of IN- must be limited to ±10mA, to prevent damage to the part.

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers 4_______________________________________________________________________________________

__________________________________________Typical Operating Characteristics

(V CC = +5V, V EE = -5V, R F = 499?, R L = 100?, T A = +25°C, unless otherwise noted.)

0.1

101

100

1000MAX4112/MAX4117/MAX4119SMALL-SIGNAL GAIN vs. FREQUENCY

(A VCL = +2)

FREQUENCY (MHz)

N O R M A L I Z E D G A I N (d B )

-6-5-3-4-1-201243

MAX4112/MAX4117/MAX4119LARGE-SIGNAL GAIN vs. FREQUENCY

(A VCL = +2)

0.1

101

100

1000

FREQUENCY (MHz)

N O R M A L I Z E D G A I N (d B )

-6

-5-3-4-1-20124

3MAX4113/MAX4118/MAX4120SMALL-SIGNAL GAIN vs. FREQUENCY

(A VCL = +8)

0.1

101

100

1000FREQUENCY (MHz)

N O R M A L I Z E D G A I N (d B )

-6-5-3-4-1-201243MAX4113/MAX4118/MAX4120SMALL-SIGNAL GAIN vs. FREQUENCY

(A VCL

= +20)

0.1

101

100

1000FREQUENCY (MHz)

N O R M A L I Z E D G A I N (d B )

-6

-5-3-4-1-201243IN OUT GND

GND

MAX4112/MAX4117/MAX4119SMALL-SIGNAL PULSE RESPONSE

(A VCL = +10)

M A X 4112-07

TIME (10ns/div)

V O L T A G E (20m V /d i v )

IN OUT GND

GND

MAX4112/MAX4117/MAX4119SMALL-SIGNAL PULSE RESPONSE

(A VCL = +2)

M A X 4112-05

TIME (10ns/div)

V O L T A G E (25m V /d i v )

MAX4113/MAX4118/MAX4120SMALL-SIGNAL GAIN vs. FREQUENCY

(A VCL = +50)

0.1

101

100

1000

FREQUENCY (MHz)

N O R M A L I Z E D G A I N (d B )

-6

-5-3-4-1-201243IN OUT

GND

GND

MAX4112/MAX4117/MAX4119LARGE-SIGNAL PULSE RESPONSE

(A VCL = +2)

M A X 4112-08

TIME (10ns/div)

V O L T A G E (1V /d i v )

MAX4112/MAX4117/MAX4119SMALL-SIGNAL GAIN vs. FREQUENCY

(A VCL = +5, +10)

M A X 4112-i n s e r t A

0.1

101

100

1000

FREQUENCY (MHz)

N

O R M A L I Z E D G A I N (d B )

-6

-5-3-4-1-201243

MAX4112/MAX4113/MAX4117–MAX4120

Single/Dual/Quad, 400MHz, Low-Power,

Current Feedback Amplifiers

_______________________________________________________________________________________

5

IN OUT GND

GND

MAX4112/MAX4117/MAX4119LARGE-SIGNAL PULSE RESPONSE

(A VCL = +10)

M A X 4112-10

TIME (10ns/div)

V O L T A G E (1V /d i v )

IN OUT GND

GND

MAX4112/MAX4117/MAX4119SMALL-SIGNAL PULSE RESPONSE

(A VCL = +2, C L = 10pF)

M A X 4112-12

TIME (10ns/div)

V O L T A G E (50m V /d i v )

IN OUT

GND

GND

MAX4113/MAX4118/MAX4120SMALL-SIGNAL PULSE RESPONSE

(A VCL = +8)

M A X 4112-13

TIME (10ns/div)

V O L T A G E (20m V /d i v )

IN

OUT

GND

GND

MAX4113/MAX4118/MAX4120LARGE-SIGNAL PULSE RESPONSE

(A VCL = +20)

M A X 4112-16

TIME (10ns/div)

V O L T A G E (1V /d i v )

IN OUT GND

GND

MAX4113/MAX4118/MAX4120SMALL-SIGNAL PULSE RESPONSE

(A VCL = +20)

M A X 4112-14

TIME (10ns/div)V O L T A G E (20m V /d i v )

IN OUT GND

GND

MAX4113/MAX4118/MAX4120LARGE-SIGNAL PULSE RESPONSE

(A VCL = +8)

M A X 4112-15

TIME (10ns/div)V O L T A G E (1V /d i v )

3020

10

02

4

68

10

MAX4112/MAX4117/MAX4119SETTLING TIME vs. GAIN

M A X 4112/4113 -17a

GAIN (V/V)

S E T T L I N G T I M E (n s )

-120

-110-90-100-70-80-60-50-40-20

-300.1101100

MAX4117–MAX4120 CROSSTALK vs. FREQUENCY

M A X 4112/4113-18a

FREQUENCY (MHz)

A M P L I T U D E (d

B )

403530252015

108

16

24

3240

48

56

MAX4113/MAX4118/MAX4120SETTLING TIME vs. GAIN

M A X 4112/4113 -17b

GAIN (V/V)

S E T T L I N G T I M E (n s )

____________________________Typical Operating Characteristics (continued)

(V CC = +5V, V EE = -5V, R F = 499?, R L = 100?, T A = +25°C, unless otherwise noted.)

-100

-80-20

LOAD RESISTANCE (?)

H A R M O N I C D I S T O R T I O N (d B c )

-40-60-90

-70-10-30-50MAX4112/MAX4117/MAX41195MHz HARMONIC DISTORTION

vs. LOAD RESISTANCE

600

1000

400

800

200

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers 6_______________________________________________________________________________________

____________________________Typical Operating Characteristics (continued)

(V CC = +5V, V EE = -5V, R F = 499?, R L = 100?, T A = +25°C, unless otherwise noted.)

1

10

100100k 10k

1k

100

10

1

10M

1M

INPUT VOLTAGE NOISE vs. FREQUENCY

FREQUENCY (Hz)

N O I S E (n V /√H z )

10100

1000

100k 10k

1k

100

10

1

10M

1M

MAX4112/MAX4117/MAX4119INPUT CURRENT NOISE vs. FREQUENCY

FREQUENCY (Hz)

N O I S E (p A /√H z )

110

1000

100

100k

10k

1k

100

10

1

10M

1M

MAX4113/MAX4118/MAX4120INPUT CURRENT NOISE vs. FREQUENCY

M A X 4112/4113-21

FREQUENCY (Hz)

N O I S E (p A /√H z

)

1000100

10

1

0.10.1

10

1

100

500

CLOSED-LOOP OUTPUT IMPEDANCE

vs. FREQUENCY

M A X 4112/4113-22

FREQUENCY (MHz)

O U T P U T I M P E D A N C E (?)

-100

-90

-80-70-60-50-40-30-20-100

0.1

1

10

100

MAX4112/MAX4117/MAX4119HARMONIC DISTORTION vs. FREQUENCY

FREQUENCY (MHz)

H A R M O N I C D I S T O R T I O N (d B c )

-100

-90-80-70-60-50-40-30-20-1000.1

1

10

100MAX4113/MAX4118/MAX4120

HARMONIC DISTORTION vs. FREQUENCY

FREQUENCY (MHz)

H A R M O N I C D I S T O R T I O N (d B c )

00.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

MAX4112/MAX4117/MAX41195MHz HARMONIC DISTORTION

vs. OUTPUT SWING

-80-20OUTPUT SWING (V P-P )

H A R M O N I C D I S T O R T I O N (d B c )

-40-60-90

-70-10-30-50-515355575951050.1

101

100

1000

POWER-SUPPLY REJECTION

vs. FREQUENCY

M A X 4112/4113-18b

FREQUENCY (MHz)

P O W E R -S U P P L Y R E J E C T I O N (d B )

MAX4112/MAX4113/MAX4117–MAX4120

Single/Dual/Quad, 400MHz, Low-Power,

Current Feedback Amplifiers

_______________________________________________________________________________________7

0-100

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

MAX4113/MAX4118/MAX41205MHz HARMONIC DISTORTION

vs. OUTPUT SWING

-80-20

OUTPUT VOLTAGE SWING (V P-P )H A R M O N I C D I S T O R T I O N (d B c )

-40-60-90-70-10-30-500-100

600

1000

MAX4113/MAX4118/MAX41205MHz HARMONIC DISTORTION

vs. LOAD RESISTANCE

-80-20

LOAD RESISTANCE (?)

H A R M O N I C D I S T O R T I O N (d B c )

400

800

200

-40-60-90

-70-10-30-500

51015202530

35400.1110100

TWO-TONE THIRD-ORDER INTERCEPT

vs. FREQUENCY

FREQUENCY (MHz)

T H I R D -O R D E R I N T E R C E P T (d B m )

900

800700600500400300

200

-75

-50

-25

25

50

75

100125

OPEN-LOOP TRANSIMPEDANCE

vs. TEMPERATURE

TEMPERATURE (°C)

T R A N S I M P E D A N C E (k ?)

4.404.204.003.803.60

3.403.203.00

POSITIVE OUTPUT-VOLTAGE SWING

vs. TEMPERATURE

M A X 4112/4113-34a

TEMPERATURE (°C)

O U T P U T V O L T A G E S W I N G (V )

-75

-50

-25

25

50

75

100125

0.0050.000-0.005-0.010-0.015-0.020-0.0250

IRE

IRE

R L = 150?

R L = 150?

100M A X 4112/4113-31

G A I N (%)

0.000.010.020.030.04-0.01

100

P H A S E (d e g r e e s )

MAX4112/MAX4117/MAX4119DIFFERENTIAL GAIN and PHASE

MAX4113/MAX4118/MAX4120DIFFERENTIAL GAIN and PHASE

-0.0050.0000.0050.0100.0150.0200.0250

IRE

IRE

100

M A X 4112/4113-32

G A I N (%)

0.000.020.04-0.06

-0.04-0.020

100

P H A S E (d e g r e e s )

R L = 150?

R L = 150?-4.40

-4.20-4.00-3.80-3.60-3.40-3.20-3.00NEGATIVE OUTPUT-VOLTAGE SWING

vs. TEMPERATURE

M A X 4112/4113-34b

TEMPERATURE (°C)

O U T P U T V O L T A G E S W I N G (V )

-75

-50-250255075100125

-2.00-2.50-3.00-3.50-4.00-4.50-5.00

POSITIVE INPUT BIAS CURRENT

vs. TEMPERATURE

M A X 4112/4113-35a

TEMPERATURE (°C)

I N P U T B I A S C U R R E N T (μA )

-75-50-250255075100125

____________________________Typical Operating Characteristics (continued)

(V CC = +5V, V EE = -5V, R F = 499?, R L = 100?, T A = +25°C, unless otherwise noted.)

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers 8_______________________________________________________________________________________

____________________________Typical Operating Characteristics (continued)

(V CC = +5V, V EE = -5V, R F = 499?, R L = 100?, T A = +25°C, unless otherwise noted.)

-10

1

2

3

INPUT OFFSET VOLTAGE vs. TEMPERATURE

M A X 4112/4113 -37

TEMPERATURE (°C)

V O L T A G E (m V )

-75

-50

-25

0255075100125

-8.00

-6.00-4.00-2.0002.004.006.008.00 POWER-SUPPLY CURRENT

vs. TEMPERATURE (PER AMPLIFIER)

TEMPERATURE (°C)

C U R R E N T (m A )

-75

-50

-25

25

50

75

100125

012345678NEGATIVE INPUT BIAS (I B-) CURRENT vs. TEMPERATURE

M A X 4112/4113-36

TEMPERATURE (°C)

I N P U T B I A S C U R R E N T (μA )

-75

-50

-25

25

50

75

100125

7.5

7.06.56.05.55.04.54.03.5255075100125150

OUTPUT SWING vs. LOAD RESISTANCE

M A X 4112/4113-39

LOAD RESISTANCE (?)

O U T P U T S W I N G (V p -p )

3.0

_____________________________________________________________Pin Descriptions

closed-loop gains (A VCL ) of 2V/V or greater, while the MAX4113/MAX4118/MAX4120 are optimized for closed-loop gains of 8V/V or greater. These low-power,high-speed, current feedback amplifiers operate from ±5V supplies. They are designed to drive video loads with low distortion characteristics. The MAX4112/MAX4117/MAX4119’s differential gain and phase are 0.02% and 0.03°, respectively; the MAX4113/MAX4118/MAX4120 exhibit gain/phase error specifica-tions of 0.02% and 0.04°, respectively. These charac-teristics, plus a wide 0.1dB gain flatness, make the MAX4112/MAX4113/MAX4117–MAX4120 ideal for use

in broadcast and graphics video systems. The combi-nation of ultra-high speed and low power makes these parts suitable for use in general-purpose, high-speed applications, such as medical imaging, industrial instru-mentation, and communications systems.

__________Applications Information

Theory of Operation

Since these devices are current-feedback amplifiers,their open-loop transfer function is expressed as a transimpedance, ?V OUT /?I IN , or Z OL . The frequency behavior of the open-loop transimpedance is similar to the open-loop gain of a voltage feedback amplifier.That is, it has a large DC value and decreases at approximately 6dB per octave.

Analyzing the follower with gain, as shown in Figure 1,yields the following transfer function:

where G = A VCL = 1 + (R F / R G), and R IN = 1 /g M ?30?.

F

MAX4112/MAX4113/MAX4117–MAX4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers

_______________________________________________________________________________________

9

Figure 1. Current Feedback Amplifier

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers 10______________________________________________________________________________________

At low gains, G x R IN << R F . Therefore, the closed-loop bandwidth is essentially independent of closed-loop gain. Similarly, Z OL >> R F at low frequencies, so that:

Layout and Power-Supply Bypassing

The MAX4112/MAX4113/MAX4117–MAX4120 have an

RF bandwidth and consequently require careful board layout, including the possible use of constant-impedance microstrip or stripline techniques.

To realize the full AC performance of these high-speed amplifiers, pay careful attention to power-supply bypassing and board layout. The PCB should have at least two layers: a signal and power layer on one side,and a large, low-impedance ground plane on the other side. The ground plane should be as free of voids as possible. With multilayer boards, locate the ground plane on a layer that incorporates no signal or power traces.

Regardless of whether a constant-impedance board is used, observe the following guidelines when designing the board. Wire-wrapped boards are much too induc-tive, and breadboards are much too capacitive; neither should be used. IC sockets increase parasitic capaci-tance and inductance, and should not be used. In gen-eral, surface-mount components give better high-frequency performance than through-hole components.They have shorter leads and lower parasitic reac-tances. Keep lines as short and as straight as possible.Do not make 90°turns; round all corners.

Observe high-frequency bypassing techniques to maintain the amplifier’s accuracy. The bypass capaci-tors should include a 1000pF ceramic capacitor between each supply pin and the ground plane, locat-ed as close to the package as possible. Next, place a

0.01μF to 0.1μF ceramic capacitor in parallel with each 1000pF capacitor, and as close to them as possible.Then place a 10μF to 15μF low-ESR tantalum at the point of entry (to the PCB) of the power-supply pins.The power-supply trace should lead directly from the tantalum capacitor to the V CC and V EE pins. To mini-mize parasitic inductance, keep PC traces short and use surface-mount components.

Figure 2a. Inverting Gain Configuration

Figure 2b. Noninverting Gain Configuration

Choosing Feedback and Gain Resistors

The MAX4112/MAX4113/MAX4117–MAX4120 are cur-rent feedback amplifiers. Increasing feedback resistor values will decrease peaking. Use the input resistor (R G ) to change the magnitude of the gain. F igure 2shows the standard inverting and noninverting configu-rations. Notice that the gain of the noninverting circuit (F igure 2b) is 1 plus the magnitude of the inverting closed-loop gain (Table 1).

DC and Noise Errors

There are several major error sources to consider in any operational amplifier. These apply equally to the MAX4112/MAX4113/MAX4117–MAX4120. Offset-error terms are given by the equation below. Voltage and current-noise errors are root-square summed and therefore computed separately. In F igure 3, the total output offset voltage is determined by:

a)The input offset voltage (V OS ) times the closed-loop gain (1 + (R F / R G )).

b)The positive input bias current (I B+) times the source resistor (R S ) (usually 50?or 75?), plus the negative input bias current (I B-) times the parallel combination of R G and R F . In current-mode feedback amplifiers,the input bias currents may flow into or out of the device. For this reason, there is no benefit to match-ing the resistance at both inputs. The equation for total DC error is:

c) The total output-referred noise voltage is:

The MAX4112/MAX4117/MAX4119 have a very low,2nV/√Hz noise voltage. The current noise at the positive input (i n+) is 13pA/√Hz , and the current noise at the inverting input (i n-) is 14pA/√Hz .

An example of the DC error calculations, using the MAX4112 typical data and the typical operating circuit where R F = R G = 600?(R F ||R G = 300?) and R S = 50?,gives the following:

V OUT = (3.5 x 10-6x 50 + 3.5 x 10-6x 300 + 10-3) (1 + 1)V OUT = 4.45mV

Calculating total output noise in a similar manner yields:

With a 200MHz system bandwidth, this calculates to 133μV RMS (approximately 797μV P-P , choosing the six-sigma value).

Resistor Types

Surface-mount resistors are the best choice for high-frequency circuits. They are of similar material to metal-film resistors, but are deposited using a thick-film process in a flat, linear manner that minimizes induc-tance. Their small size and lack of leads also minimizes parasitic inductance and capacitance, yielding more predictable performance.

Metal-film resistors with leads are manufactured using a thin-film process where resistive material is deposited in a spiral layer around a ceramic rod. Although the materials used are noninductive, the spiral winding pre-sents a small inductance (about 5nH) that may have an adverse effect on high-frequency circuits.

Carbon-composition resistors with leads are manufac-tured by pouring the resistor material into a mold. This process yields relatively low-inductance resistors that are very useful in high-frequency applications, although they tend to cost more and have more thermal noise than other types. The ability of carbon-composition resistors to self-heal after a large current overload makes them useful in high-power RF applications.

F or general-purpose use, surface-mount metal-film resistors seem to have the best overall performance for low cost, low inductance, and low noise.

Video Line Driver

The MAX4112/MAX4113/MAX4117–MAX4120 are opti-mized (gain flatness) to drive coaxial transmission lines when the cable is terminated at both ends, as shown in F igure 4. Cable frequency response can cause varia-tions in the flatness of the signal.

MAX4112/MAX4113/MAX4117–MAX4120

Single/Dual/Quad, 400MHz, Low-Power,

Current Feedback Amplifiers

______________________________________________________________________________________11

Figure 3. Output Offset Voltage

Driving Capacitive Loads

The MAX4112/MAX4113/MAX4117–MAX4120 are opti-mized for AC performance. They are not designed to drive highly capacitive loads. Reactive loads decrease phase margin and can produce excessive ringing and oscillation. Figure 5a shows a circuit that eliminates this problem. The small (usually 5?to 22?) isolation resis-tor, R S , placed before the reactive load prevents ring-ing and oscillation. At higher capacitive loads, AC performance is controlled by the interaction of the load capacitance and isolation resistor.

M A X 4112/M A X 4113/M A X 4117–M A X 4120

Single/Dual/Quad, 400MHz, Low-Power,Current Feedback Amplifiers Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.

12____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600?2007 Maxim Integrated Products

is a registered trademark of Maxim Integrated Products, Inc.

TRANSISTOR COUNT: 53(MAX4112/MAX4113)

112(MAX4117/MAX4118)220(MAX4119/MAX4120)SUBSTRATE CONNECTED TO V EE

Figure 4. Video Line Driver

___________________Chip Information

*Contact factory for QSOP package availability.

Revision History

Pages changed at Rev 3: 1–3, 6, 7, 10–12