Datasheet EL5420CL-T13, EL5420CL, EL5420CS-T7, EL5420CS-T13, EL5420CS Datasheet (ELANT)

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

EL5220C, EL5420C

Features

• 12MHz -3dB bandwidth

• Supply voltage = 4.5V to 16.5V

• Low supply current (per amplifier)
= 500µA

• High slew rate = 10V/µs

• Unity-gain stable

• Beyond the rails input capability

• Rail-to-rail output swing

• Ultra-small package

Applications

• TFT-LCD drive circuits

• Electronics notebooks

• Electronics games

• Touch-screen displays

• Personal communication devices

• Personal digital assistants (PDA)

• Portable instrumentation

• Sampling ADC amplifiers

• Wireless LANs

• Office automation

• Active filters

• ADC/DAC buffer

General Description

The EL5420C and EL5220C are low power, high voltage, rail-to-rail
input-output amplifiers. The EL5220C contains two amplifiers in one
package, and the EL5420C contains four amplifiers. Operating on sup­plies ranging from 5V to 15V, while consuming only 500µA per
amplifier, the EL5420C and EL5220C have a bandwidth of 12MHz --
(-3dB). They also provide common mode input ability beyond the sup­ply rails, as well as rail-to-rail output capability. This enables these
amplifiers to offer maximum dynamic range at any supply voltage.

The EL5420C and EL5220C also feature fast slewing and settling
times, as well as a high output drive capability of 30mA (sink and
source). These features make these amplifiers ideal for use as voltage
reference buffers in Thin Film Transistor Liquid Crystal Displays
(TFT-LCD). Other applications include battery power, portable
devices, and anywhere low power consumption is important.

The EL5420C is available in a space-saving 14-pin TSSOP package,
the industry-standard 14-pin SO package, as well as a 16-pin LPP
package. The EL5220C is available in the 8-pin MSOP package. Both
feature a standard operational amplifier pin out. These amplifiers are
specified for operation over the full -40°C to +85°C temperature
range.

Connection Diagrams

1

VOUTA

Ordering Information

Part No. Package

EL5220CY 8-Pin MSOP - MDP0043

EL5220CY-T7 8-Pin MSOP 7” MDP0043

EL5220CY-T13 8-Pin MSOP 13” MDP0043

EL5420CL 16-Pin LPP - MDP0046

EL5420CL-T7 16-Pin LPP 7” MDP0046

EL5420CL-T13 16-Pin LPP 13” MDP0046

EL5420CR 14-Pin TSSOP - MDP0044

EL5420CR-T7 14-Pin TSSOP 7” MDP0044

EL5420CR-T13 14-Pin TSSOP 13” MDP0044

EL5420CS 14-Pin SO - MDP0027

EL5420CS-T7 14-Pin SO 7” MDP0027

EL5420CS-T13 14-Pin SO 13” MDP0027

Note: All information contained in this data sheet has been carefully checked and is believed to be accurate as of the date of publication; however, this data sheet cannot be a “controlled document”. Current revisions, if any, to these
specifications are maintained at the factory and are available upon your request. We recommend checking the revision level before finalization of your design documentation.

© 2001 Elantec Semiconductor, Inc.

Tape &

Reel Outline #

2

VINA-

VINA+

VINB+

VINB-

VOUTB

Connection Diagrams are continued on page 4

-

3

+

4

5

+

6

-

7

EL5420C

(14-Pin TSSOP & 14-Pin SO)

14

VOUTD

13

VIND-

­12

+

VIND+

1

11

VS-VS+

10

VINC+

+

9

-

VINC-

8

VOUTC

VOUTA

VINA-

VINA+

VS-

2

3

4

­+

EL5220C

(8-Pin MSOP)

8

VS+

7

VOUTB

65-

VINB-

+

VINB+

September 19, 2001

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Absolute Maximum Ratings (T

Values beyond absolute maximum ratings can cause the device to be pre­maturely damaged. Absolute maximum ratings are stress ratings only

EL5220C, EL5420C

and functional device operation is not implied

Supply Voltage between VS+ and VS- +18V

Input Voltage VS- - 0.5V, VS +0.5V

Maximum Continuous Output Current 30mA

= 25°C)

A

Maximum Die Temperature +125°C

Storage Temperature -65°C to +150°C

Operating Temperature -40°C to +85°C

Power Dissipation See Curves

ESD Voltage 2kV

Important Note:

All parameters having Min/Max specifications are guaranteed. Typ values are for information purposes only. Unless otherwise noted, all tests are at the
specified temperature and are pulsed tests, therefore: TJ = TC = T

A

Electrical Characteristics

VS+= +5V, VS - = -5V, R

Parameter Description Condition Min Typ Max Unit

Input Characteristics

V

OS

TCV

OS

I

B

R

IN

C

IN

CMIR Common-Mode Input Range -5.5 +5.5 V

CMRR Common-Mode Rejection Ratio for VIN from -5.5V to +5.5V 50 70 dB

A

VOL

Output Characteristics

V

OL

V

OH

I

SC

I

OUT

Power Supply Performance

PSRR Power Supply Rejection Ratio VS is moved from ±2.25V to ±7.75V 60 80 dB

I

S

Dynamic Performance

SR Slew Rate

t

S

BW -3dB Bandwidth R

GBWP Gain-Bandwidth Product R

PM Phase Margin R

CS Channel Separation f = 5MHz 75 dB

1. Measured over operating temperature range

2. Slew rate is measured on rising and falling edges

= 10kΩ and C

L

Input Offset Voltage V

Average Offset Voltage Drift

Input Bias Current V

= 10pF to 0V, TA = 25°C unless otherwise specified.

L

= 0V 2 12 mV

CM

[1]

= 0V 2 50 nA

CM

5 µV/°C

Input Impedance 1 GΩ

Input Capacitance 1.35 pF

Open-Loop Gain -4.5V ≤ V

≤ +4.5V 75 95 dB

OUT

Output Swing Low IL = -5mA -4.92 -4.85 V

Output Swing High IL = 5mA 4.85 4.92 V

Short Circuit Current ±120 mA

Output Current ±30 mA

Supply Current (Per Amplifier) No load 500 750 µA

[2]

-4.0V ≤ V

≤ +4.0V, 20% to 80% 10 V/µs

OUT

Settling to +0.1% (AV = +1) (AV = +1), VO = 2V step 500 ns

= 10kΩ, C

L

= 10kΩ, C

L

= 10kΩ, C

L

= 10pF 12 MHz

L

= 10pF 8 MHz

L

= 10 pF 50 °

L

2

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Electrical Characteristics

VS+ = 5V, VS-= 0V, R

Parameter Description Condition Min Typ Max Unit

Input Characteristics

V

OS

TCV

OS

I

B

R

IN

C

IN

CMIR Common-Mode Input Range -0.5 +5.5 V

CMRR Common-Mode Rejection Ratio for VIN from -0.5V to +5.5V 45 66 dB

A

VOL

Output Characteristics

V

OL

V

OH

I

SC

I

OUT

Power Supply Performance

PSRR Power Supply Rejection Ratio VS is moved from 4.5V to 15.5V 60 80 dB

I

S

Dynamic Performance

SR Slew Rate

t

S

BW -3dB Bandwidth R

GBWP Gain-Bandwidth Product R

PM Phase Margin R

CS Channel Separation f = 5MHz 75 dB

1. Measured over operating temperature range

2. Slew rate is measured on rising and falling edges

= 10kΩ and C

L

Input Offset Voltage V

Average Offset Voltage Drift

Input Bias Current V

= 10pF to 2.5V, TA = 25°C unless otherwise specified.

L

= 2.5V 2 10 mV

CM

[1]

= 2.5V 2 50 nA

CM

5 µV/°C

Input Impedance 1 GΩ

Input Capacitance 1.35 pF

Open-Loop Gain 0.5V ≤ V

≤+ 4.5V 75 95 dB

OUT

Output Swing Low IL = -5mA 80 150 mV

Output Swing High IL = +5mA 4.85 4.92 V

Short Circuit Current ±120 mA

Output Current ±30 mA

Supply Current (Per Amplifier) No load 500 750 µA

[2]

1V ≤ V

≤ 4V, 20% to 80% 10 V/µs

OUT

Settling to +0.1% (AV = +1) (AV = +1), VO = 2V step 500 ns

= 10kΩ, C

L

= 10 kΩ, C

L

= 10 kΩ, C

L

= 10pF 12 MHz

L

= 10pF 8 MHz

L

= 10 pF 50 °

L

EL5220C, EL5420C

Electrical Characteristics

VS+ = 15V, VS- = 0V, R

Parameter Description Condition Min Typ Max Unit

Input Characteristics

V

OS

TCV

OS

I

B

R

IN

C

IN

CMIR Common-Mode Input Range -0.5 +15.5 V

CMRR Common-Mode Rejection Ratio for VIN from -0.5V to +15.5V 53 72 dB

A

VOL

Output Characteristics

V

OL

V

OH

= 10kΩ and C

L

Input Offset Voltage V

Average Offset Voltage Drift

Input Bias Current V

= 10pF to 7.5V, TA = 25°C unless otherwise specified.

L

= 7.5V 2 14 mV

CM

[1]

= 7.5V 2 50 nA

CM

5 µV/°C

Input Impedance 1 GΩ

Input Capacitance 1.35 pF

Open-Loop Gain 0.5V ≤ V

≤ 14.5V 75 95 dB

OUT

Output Swing Low IL = -5mA 80 150 mV

Output Swing High IL = +5mA 14.85 14.92 V

3

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Electrical Characteristics (Continued)

VS+ = 15V, VS- = 0V, R

Parameter Description Condition Min Typ Max Unit

EL5220C, EL5420C

I

SC

I

OUT

Power Supply Performance

PSRR Power Supply Rejection Ratio VS is moved from 4.5V to 15.5V 60 80 dB

I

S

Dynamic Performance

SR Slew Rate

t

S

BW -3dB Bandwidth R

GBWP Gain-Bandwidth Product R

PM Phase Margin R

CS Channel Separation f = 5MHz 75 dB

1. Measured over operating temperature range

2. Slew rate is measured on rising and falling edges

Connection Diagrams (Continued)

= 10kΩ and C

L

= 10pF to 7.5V, TA = 25°C unless otherwise specified.

L

Short Circuit Current ±120 mA

Output Current ±30 mA

Supply Current (Per Amplifier) No load 500 750 µA

[2]

1V ≤ V

≤ 14V, 20% to 80% 10 V/µs

OUT

Settling to +0.1% (AV = +1) (AV = +1), VO = 2V step 500 ns

= 10kΩ, C

L

= 10kΩ, C

L

= 10kΩ, C

L

= 10pF 12 MHz

L

= 10pF 8 MHz

L

= 10 pF 50 °

L

VINA-

VINA+

VS+

VINB+

NC

VOUTA

VOUTD

16

15

1

2

Thermal Pad

3

4

5

6

VINB-

VOUTB

EL5420C

(16-Pin LPP)

NC

14

13

12

VIND-

11

VIND+

10

VS-

9

VINC+

7

8

VINC-

VOUTC

4

Typical Performance Curves

EL5220C, EL5420C

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

EL5420C Input Offset Voltage Distribution

1800

VS=±5V

1600

TA=25°C

1400
1200
1000

800
600

Quantity (Amplifiers)

400
200

0

10

5

0

Input Offset Voltage (mV)

-5

-8-6-4-2-0

-12

-10
Input Offset Voltage (mV)

Input Offset Voltage vs Temperature

0 150

Temperature (°C)

246

50-50 100

Typical
Production
Distribution

8

10

VS=±5V

EL5420C Input Offset Voltage Drift

70

VS=±5V

60

50

40

30

Quantity (Amplifiers)

20

10

0

1

3

5

7

9

12

2.0

0.0

Input Bias Current (nA)

-2.0

Input Offset Voltage Drift, TCVOS (µV/°C)

Input Bias Current vs Temperature

VS=±5V

0 15050-50 100

11

Temperature (°C)

Typical
Production
Distribution

13

15

17

19

21

Output High Voltage vs Temperature

4.97

4.96

4.95

Output High Voltage (V)

4.94

4.93
0 150

50-50 100

Temperature (°C)

VS=±5V

I

OUT

=5mA

Output Low Voltage vs Temperature

-4.91

-4.92

-4.93

-4.94

-4.95

Output Low Voltage (V)

-4.96

-4.97

VS=±5V

I

=-5mA

OUT

0 150

50-50 100

Temperature (°C)

5

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Typical Performance Curves

EL5220C, EL5420C

Open-Loop Gain vs Temperature

100

90

Open-Loop Gain (dB)

80

0 150

50-50 100

Temperature (°C)

EL5420C Supply Current per Amplifier vs Temperature

0.55

0.5

Supply Current (mA)

0.45
0 150

50-50 100

Temperature (°C)

VS=±5V

RL=10kΩ

VS=±5V

Slew Rate vs Temperature

10.40

10.35

10.30

Slew Rate (V/µS)

10.25

0 150

EL5420C Supply Current per Amplifier vs Supply Voltage

700

TA=25°C

600

500

Supply Current (µA)

400

300

5 20

50-50 100

Temperature (°C)

100

Supply Voltage (V)

VS=±5V

15

Open Loop Gain and Phase vs Frequency

200

150

100

Gain (dB)

50

VS=±5V, TA=25°C
RL=10KΩ to GND

0

CL=12pF to GND

-50
10 10k 100M

100 1k 100k 1M 10M

Phase

Gain

Frequency (Hz)

20

-30

-80

-130

-180

-230

Frequency Response for Various R

5

0

CL=10pF

-5

Phase(°)

AV=1
VS=±5V

-10

Magnitude (Normalized) (dB)

-15
100k

1M

Frequency (Hz)

L

10kΩ

1kΩ
560Ω
150Ω

10M

100M

6

Typical Performance Curves

EL5220C, EL5420C

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Frequency Response for Various C

20

RL=10kΩ

10

AV=1
VS=±5V

0

-10

-20

Magnitude (Normalized) (dB)

-30
100k

Maximum Output Swing vs Frequency

12

)

10

P-P

8

6

VS=±5V
TA=25°C

4

AV=1
RL=10kΩ

Maximum Output Swing (V

2

CL=12pF
Distortion <1%

0

10k 100

1000pF

1M

Frequency (Hz)

Frequency (Hz)

L

12pF
50pF

100pF

10M

1M

100M

10M

Closed Loop Output Impedance vs Frequency

200

AV=1

160

VS=±5V
TA=25°C

120

80

Output Impedance (Ω)

40

0

10k 100

CMRR vs Frequency

80

60

40

CMRR (dB)

20

VS=±5V
TA=25°C

0

100

Frequency (Hz)

1k

10k
Frequency (Hz)

100k

1M

10M

1M

10M

80

60

40

PSRR (dB)

20

0

100

PSRR vs Frequency

PSRR+

PSRR-

VS=±5V
TA=25°C

1k

10k

Frequency (Hz)

100k

Input Voltage Noise Spectral Density vs Frequency

600

100

10

Voltage Noise (nV√Hz)

1

1M

10M

100 100k 100M

Frequency (Hz)

10M1k 10k 1M

7

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Typical Performance Curves

EL5220C, EL5420C

Total Harmonic Distortion + Noise vs Frequency

0.010

0.009

0.008

0.007

0.006

0.005

THD+ N (%)

0.004
VS=±5V

RL=10kΩ

0.003
AV=1

0.002

VIN=1V

RMS

1k 10k 100k

Small-Signal Overshoot vs Load Capacitance

VS=±5V
AV=1
RL=10kΩ
VIN=±50mV
TA=25°C

Frequency (Hz)

Overshoot (%)

0.001

90

70

50

30

10

Channel Separation vs Frequency Response

-60
Dual measured Channel A to B
Quad measured Channel A to D or B to C
Other combinations yield improved rejection

-80
VS=±5V

RL=10kΩ
AV=1
VIN=220mV

-100

X-Talk (dB)

-120

-140
1k

Settling Time vs Step Size

VS=±5V

4

AV=1

3

RL=10kΩ
CL=12pF

2

TA=25°C

1
0

-1

Step Size (V)

-2

-3

-4

RMS

Frequency (Hz)

1M 6M10k 100k

0.1%

0.1%

10 100 1000

Large Signal Transient Response

1V 1µS

Load Capacitance (pF)

VS=±5V
TA=25°C
AV=1
RL=10kΩ
CL=12pF

VS=±5V
TA=25°C
AV=1
RL=10kΩ
CL=12pF

800

200 400

Settling Time (nS)

Small Signal Transient Response

50mV 200ns

6000

8

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Pin Descriptions

EL5420C EL5220C Pin Name Pin Function Equivalent Circuit

1 1 VOUTA Amplifier A Output

GND

Circuit 1

2 2 VINA- Amplifier A Inverting Input

EL5220C, EL5420C

V

S+

V

S-

V

S+

3 3 VINA+ Amplifier A Non-Inverting Input (Reference Circuit 2)

4 8 VS+ Positive Power Supply

5 5 VINB+ Amplifier B Non-Inverting Input (Reference Circuit 2)

6 6 VINB- Amplifier B Inverting Input (Reference Circuit 2)

7 7 VOUTB Amplifier B Output (Reference Circuit 1)

8 VOUTC Amplifier C Output (Reference Circuit 1)

9 VINC- Amplifier C Inverting Input (Reference Circuit 2)

10 VINC+ Amplifier C Non-Inverting Input (Reference Circuit 2)

11 4 VS- Negative Power Supply

12 VIND+ Amplifier D Non-Inverting Input (Reference Circuit 2)

13 VIND- Amplifier D Inverting Input (Reference Circuit 2)

14 VOUTD Amplifier D Output (Reference Circuit 1)

Circuit 2

V

S-

9

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

Applications Information

Product Description

EL5220C, EL5420C

The EL5220C and EL5420C voltage feedback amplifi­ers are fabricated using a high voltage CMOS process.
They exhibit rail-to-rail input and output capability, they
are unity gain stable, and have low power consumption
(500µA per amplifier). These features make the
EL5220C and EL5420C ideal for a wide range of gen­eral-purpose applications. Connected in voltage follower

mode and driving a load of 10kΩ and 12pF, the

EL5220C and EL5420C have a -3dB bandwidth of
12MHz while maintaining a 10V/µs slew rate. The
EL5220C is a dual amplifier while the EL5420C is a
quad amplifier.

VS=±5V
TA=25°C
AV=1
VIN=10V

P-P

Output Input

Figure 1. Operation with Rail-to-Rail Input and

Output

Operating Voltage, Input, and Output

The EL5220C and EL5420C are specified with a single
nominal supply voltage from 5V to 15V or a split supply
with its total range from 5V to 15V. Correct operation is
guaranteed for a supply range of 4.5V to 16.5V. Most
EL5220C and EL5420C specifications are stable over
both the full supply range and operating temperatures of

-40 °C to +85 °C. Parameter variations with operating
voltage and/or temperature are shown in the typical per­formance curves.

The input common-mode voltage range of the EL5220C
and EL5420C extends 500mV beyond the supply rails.
The output swings of the EL5220C and EL5420C typi­cally extend to within 80mV of positive and negative
supply rails with load currents of 5mA. Decreasing load
currents will extend the output voltage range even closer
to the supply rails. Figure 1 shows the input and output
waveforms for the device in the unity-gain configura-

tion. Operation is from ±5V supply with a 10kΩ load

connected to GND. The input is a 10V
output voltage is approximately 9.985V

sinusoid. The

P-P

.

P-P

Short Circuit Current Limit

The EL5220C and EL5420C will limit the short circuit
current to ±120mA if the output is directly shorted to the
positive or the negative supply. If an output is shorted
indefinitely, the power dissipation could easily increase
such that the device may be damaged. Maximum reli­ability is maintained if the output continuous current
never exceeds ±30 mA. This limit is set by the design of
the internal metal interconnects.

Output Phase Reversal

The EL5220C and EL5420C are immune to phase rever­sal as long as the input voltage is limited from (VS-) ----

-0.5V to (VS+) +0.5V. Figure 2 shows a photo of the
output of the device with the input voltage driven
beyond the supply rails. Although the device's output
will not change phase, the input's overvoltage should be
avoided. If an input voltage exceeds supply voltage by
more than 0.6V, electrostatic protection diodes placed in
the input stage of the device begin to conduct and over­voltage damage could occur.

10

1V 100µs

VS=±2.5V
TA=25°C
AV=1
VIN=6V

P-P

1V

Figure 2. Operation with Beyond-the-Rails

Input

Power Dissipation

With the high-output drive capability of the EL5220C
and EL5420C amplifiers, it is possible to exceed the
125°C “absolute-maximum junction temperature” under
certain load current conditions. Therefore, it is important
to calculate the maximum junction temperature for the
application to determine if load conditions need to be
modified for the amplifier to remain in the safe operating
area.

The maximum power dissipation allowed in a package is
determined according to:

T

–

JMAXTAMAX

P

DMAX

where:

T

= Maximum Junction Temperature

JMAX

T

= Maximum Ambient Temperature

AMAX

θ

= Thermal Resistance of the Package

JA

P

= Maximum Power Dissipation in the Package

DMAX

The maximum power dissipation actually produced by
an IC is the total quiescent supply current times the total
power supply voltage, plus the power in the IC due to the
loads, or:

------------------------------------------------

=

Θ

JA

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

when sourcing, and:

P

when sinking.

where

i = 1 to 2 for Dual and 1 to 4 for Quad

VS = Total Supply Voltage

I

SMAX

V

OUT

I

LOAD

If we set the two P
we can solve for R
ures 3, 4, and 5 provide a convenient way to see if the
device will overheat. The maximum safe power dissipa­tion can be found graphically, based on the package type
and the ambient temperature. By using the previous
equation, it is a simple matter to see if P
the device's power derating curves. To ensure proper
operation, it is important to observe the recommended
derating curves in Figures 3, 4, and 5.

Power Dissipation (mW)

Figure 3. Package Power Dissipation vs

DMAX

ΣiV

SISMAXVOUT

i( VS- ) I

LOAD

= Maximum Supply Current Per Amplifier

i = Maximum Output Voltage of the Application

i = Load Current

equations equal to each other,

DMAX

i to avoid device overheat. Fig-

LOAD

exceeds

DMAX

JEDEC JESD51-7 High Effective Thermal Conductivity (4­Layer) Test Board

LPP exposed diepad soldered to PCB per JESD51-5

1200

1000

800

600

400

200

0

1.136W

1.0W

870mW

0

TSSOP14

θJA=100°C/W

MSOP8

θJA=115°C/W

25 50 75 100 125 15085

Ambient Temperature (°C)

MAX TJ=125°C

SO14

θJA=88°C/W

Ambient Temperature

i×–+×[]×=

EL5220C, EL5420C

P

DMAX

ΣiV

SISMAXVS

+( V

OUT

i ) I

LOAD

i×–+×[]×=

11

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

JEDEC JESD51-3 and SEMI G42-88 (Single Layer) Test
Board

1200

EL5220C, EL5420C

1000

833mW

800

667mW

600

606mW
485mW

400

Power Dissipation (mW)

200

0

0

SO14

θJA=120°C/W

MSOP8

θJA=206°C/W

25 50 75 100 125 15085

Ambient Temperature (°C)

LPP16

θJA=150°C/W

Figure 4. Package Power Dissipation vs

Ambient Temperature

JEDEC JESD51-7 High Effective Thermal Conductivity (4­Layer) Test Board

(LPP exposed diepad soldered to PCB per JESD51-5)

3

2.500W

2.5

2

1.5

1

Power Dissipation (W)

0.5

0

0 25 50 75 100 125 150

L

P

P

1

4

6

0

°

C

/

W

85

Ambient Temperature (°C)

Figure 5. Package Power Dissipation vs

Ambient Temperature

MAX TJ=125°C

TSSOP14

θJA=165°C/W

the peaking increase. The amplifiers drive 10pF loads in

parallel with 10kΩ with just 1.5dB of peaking, and

100pF with 6.4dB of peaking. If less peaking is desired
in these applications, a small series resistor (usually

between 5Ω and 50Ω) can be placed in series with the

output. However, this will obviously reduce the gain
slightly. Another method of reducing peaking is to add a
“snubber” circuit at the output. A snubber is a shunt load
consisting of a resistor in series with a capacitor. Values

of 150Ω and 10nF are typical. The advantage of a snub-

ber is that it does not draw any DC load current or
reduce the gain

Power Supply Bypassing and Printed Circuit
Board Layout

The EL5220C and EL5420C can provide gain at high
frequency. As with any high-frequency device, good
printed circuit board layout is necessary for optimum
performance. Ground plane construction is highly rec­ommended, lead lengths should be as short as possible
and the power supply pins must be well bypassed to
reduce the risk of oscillation. For normal single supply
operation, where the VS- pin is connected to ground, a

0.1µF ceramic capacitor should be placed from VS+ to
pin to VS- pin. A 4.7µF tantalum capacitor should then
be connected in parallel, placed in the region of the
amplifier. One 4.7µF capacitor may be used for multiple
devices. This same capacitor combination should be
placed at each supply pin to ground if split supplies are
to be used.

Unused Amplifiers

It is recommended that any unused amplifiers in a dual
and a quad package be configured as a unity gain fol­lower. The inverting input should be directly connected
to the output and the non-inverting input tied to the
ground plane.

Driving Capacitive Loads

The EL5220C and EL5420C can drive a wide range of
capacitive loads. As load capacitance increases, how­ever, the -3dB bandwidth of the device will decrease and

12

EL5220C, EL5420C

12MHz Rail-to-Rail Input-Output Op Amps

EL5220C, EL5420C

General Disclaimer

Specifications contained in this data sheet are in effect as of the publication date shown. Elantec, Inc. reserves the right to make changes in the cir­cuitry or specifications contained herein at any time without notice. Elantec, Inc. assumes no responsibility for the use of any circuits described
herein and makes no representations that they are free from patent infringement.

WARNING - Life Support Policy

Elantec, Inc. products are not authorized for and should not be used
within Life Support Systems without the specific written consent of
Elantec, Inc. Life Support systems are equipment intended to sup-

Elantec Semiconductor, Inc.

675 Trade Zone Blvd.
Milpitas, CA 95035
Telephone: (408) 945-1323

(888) ELANTEC
Fax: (408) 945-9305
European Office: +44-118-977-6020
Japan Technical Center: +81-45-682-5820

port or sustain life and whose failure to perform when properly used
in accordance with instructions provided can be reasonably
expected to result in significant personal injury or death. Users con­templating application of Elantec, Inc. Products in Life Support
Systems are requested to contact Elantec, Inc. factory headquarters
to establish suitable terms & conditions for these applications. Elan­tec, Inc.’s warranty is limited to replacement of defective
components and does not cover injury to persons or property or
other consequential damages.

September 19, 2001

13

Printed in U.S.A.