File Number

4230.1

CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.

HS-1412RH

Radiation Hardened, Quad, High Speed,
Low Power, Video Closed Loop Buffer

The HS-1412RH is a radiation hardened quad closed loop
buffer featuring user programmable gain and high speed
performance. Manufactured on Intersil's proprietary
complementary bipolar UHF-1 (DI bonded wafer) process,
this device offers wide -3dB bandwidth of 340MHz, very fast
slew rate, excellent gain flatness and high output current.
These devices are QML approved and are processed and
screened in full compliance with MIL-PRF-38535.

A unique feature of the pinout allows the user to select a
voltage gain of +1, -1, or +2, without the use of any external
components. Gain selection is accomplished via
connections to the inputs, as described in the "Application
Information" section. The result is a more flexible product,
fewer part types in inventory, and more efficient use of board
space.

Compatibility with existing op amp pinouts provides flexibility
to upgrade low gain amplifiers, while decreasing component
count. Unlike most buffers, the standard pinout provides an
upgrade path should a higher closed loop gain be needed at
a future date.

Specifications for Rad Hard QML devices are controlled
by the Defense Supply Center in Columbus (DSCC). The
SMD numbers listed here must be used when ordering.

Detailed Electrical Specifications for these devices are
contained in SMD 5962-96834. A "hot-link" is provided
on our homepage for downloading.
www.intersil.com/spacedefense/space.asp

Features

· Electrically Screened to SMD # 5962-96834

· QML Qualified per MIL-PRF-38535 Requirements

· MIL-PRF-38535 Class V Compliant

· User Programmable For Closed-Loop Gains of +1, -1 or

+2 Without Use of External Resistors

· Standard Operational Amplifier Pinout

· Low Supply Current . . . . . . . . . . . . 5.9mA/Op Amp (Typ)

· Excellent Gain Accuracy . . . . . . . . . . . . . . . 0.99V/V (Typ)

· Wide -3dB Bandwidth. . . . . . . . . . . . . . . . . .340MHz (Typ)

· Fast Slew Rate . . . . . . . . . . . . . . . . . . . . . .1155V/

s (Typ)

· High Input Impedance . . . . . . . . . . . . . . . . . . . 1M

(Typ)

· Excellent Gain Flatness (to 50MHz) . . . . . .

0.02dB (Typ)

· Fast Overdrive Recovery . . . . . . . . . . . . . . . . <10ns (Typ)

· Total Gamma Dose. . . . . . . . . . . . . . . . . . . . 300kRAD(Si)

· Latch Up . . . . . . . . . . . . . . . . . . . . . None (DI Technology)

Applications

· Flash A/D Driver

· Video Switching and Routing

· Pulse and Video Amplifiers

· Wideband Amplifiers

· RF/IF Signal Processing

· Imaging Systems

Pinout

HS-1412RH (CERDIP) GDIP1-T14

HS-1412RH (SBDIP) CDIP2-T14

TOP VIEW

Ordering Information

ORDERING NUMBER

INTERNAL

MKT. NUMBER

TEMP. RANGE

(

5962F9683401VCA

HS1-1412RH-Q

-55 to 125

5962F9683401VCC

HS1B-1412RH-Q

-55 to 125

OUT1

-IN1

+IN1

V+

+IN2

-IN2

OUT2

OUT4

-IN4

+IN4

V-

+IN3

-IN3

OUT3

Data Sheet

August 1999

Application Information

HS-1412RH Advantages

The HS-1412RH features a novel design which allows the
user to select from three closed loop gains, without any
external components. The result is a more flexible product,
fewer part types in inventory, and more efficient use of board
space. Implementing a quad, gain of 2, cable driver with this
IC eliminates the eight gain setting resistors, which frees up
board space for termination resistors.

Like most newer high performance amplifiers, the HS-1412RH
is a current feedback amplifier (CFA). CFAs offer high
bandwidth and slew rate at low supply currents, but can be
difficult to use because of their sensitivity to feedback
capacitance and parasitics on the inverting input (summing
node). The HS-1412RH eliminates these concerns by bringing
the gain setting resistors on-chip. This yields the optimum
placement and value of the feedback resistor, while minimizing
feedback and summing node parasitics. Because there is no
access to the summing node, the PCB parasitics do not impact
performance at gains of +2 or -1 (see "Unity Gain
Considerations" for discussion of parasitic impact on unity gain
performance).

The HS-1412RH's closed loop gain implementation provides
better gain accuracy, lower offset and output impedance,
and better distortion compared with open loop buffers.

Closed Loop Gain Selection

This "buffer" operates in closed loop gains of -1, +1, or +2,
with gain selection accomplished via connections to the

inputs. Applying the input signal to +IN and floating -IN

selects a gain of +1 (see next section for layout caveats),
while grounding -IN selects a gain of +2. A gain of -1 is
obtained by applying the input signal to -IN with +IN
grounded through a 50

resistor.

The table below summarizes these connections:

Unity Gain Considerations

Unity gain selection is accomplished by floating the -Input of
the HS-1412RH. Anything that tends to short the -Input to
GND, such as stray capacitance at high frequencies, will
cause the amplifier gain to increase toward a gain of +2. The
result is excessive high frequency peaking, and possible
instability. Even the minimal amount of capacitance
associated with attaching the -Input lead to the PCB results
in approximately 6dB of gain peaking. At a minimum this
requires due care to ensure the minimum capacitance at the
-Input connection.

Table 1 lists five alternate methods for configuring the
HS-1412RH as a unity gain buffer, and the corresponding
performance. The implementations vary in complexity and
involve performance trade-offs. The easiest approach to
implement is simply shorting the two input pins together,
and applying the input signal to this common node. The
amplifier bandwidth decreases from 550MHz to 370MHz,
but excellent gain flatness is the benefit. A drawback to this
approach is that the amplifier input noise voltage and input
offset voltage terms see a gain of +2, resulting in higher
noise and output offset voltages. Alternately, a 100pF
capacitor between the inputs shorts them only at high
frequencies, which prevents the increased output offset
voltage but delivers less gain flatness.

Another straightforward approach is to add a 620

resistor

in series with the amplifier's positive input. This resistor and
the HS-1412RH input capacitance form a low pass filter
which rolls off the signal bandwidth before gain peaking
occurs. This configuration was employed to obtain the data
sheet AC and transient parameters for a gain of +1.

Pulse Overshoot

The HS-1412RH utilizes a quasi-complementary output stage
to achieve high output current while minimizing quiescent
supply current. In this approach, a composite device replaces
the traditional PNP pulldown transistor. The composite device
switches modes after crossing 0V, resulting in added
distortion for signals swinging below ground, and an
increased overshoot on the negative portion of the output
waveform (see Figure 5, Figure 7, and Figure 9). This
overshoot isn't present for small bipolar signals (see Figure 4,
Figure 6, and Figure 8) or large positive signals. Figure 28
through Figure 31 illustrate the amplifier's overshoot
dependency on input transition time, and signal polarity.

GAIN
(A

)

CONNECTIONS

+INPUT

-INPUT

-1

to GND

Input

NC (Floating)

Input

GND

TABLE 1. UNITY GAIN PERFORMANCE FOR VARIOUS IMPLEMENTATIONS

APPROACH

PEAKING (dB)

BW (MHz)

SR (V/

0.1dB GAIN FLATNESS (MHz)

Remove -IN Pin

5.0

550

1300

= 620

1.0

230

1000

= 620

and Remove -IN Pin

0.7

225

1000

Short +IN to -IN (e.g., Pins 2 and 3)

0.1

370

500

170

100pF Capacitor Between +IN and -IN

0.3

380

550

130

HS-1412RH

PC Board Layout

This amplifier's frequency response depends greatly on the
care taken in designing the PC board (PCB). The use of low
inductance components such as chip resistors and chip
capacitors is strongly recommended, while a solid
ground plane is a must!

Attention should be given to decoupling the power supplies.
A large value (10

F) tantalum in parallel with a small value

(0.1

F) chip capacitor works well in most cases.

Terminated microstrip signal lines are recommended at the
input and output of the device. Capacitance directly on the
output must be minimized, or isolated as discussed in the
next section.

An example of a good high frequency layout is the
Evaluation Board shown in Figure 3.

Driving Capacitive Loads

Capacitive loads, such as an A/D input, or an improperly
terminated transmission line will degrade the amplifier's
phase margin resulting in frequency response peaking and
possible oscillations. In most cases, the oscillation can be
avoided by placing a resistor (R

) in series with the output

prior to the capacitance.

Figure 1 details starting points for the selection of this
resistor. The points on the curve indicate the R

and C

combinations for the optimum bandwidth, stability, and
settling time, but experimental fine tuning is recommended.
Picking a point above or to the right of the curve yields an
overdamped response, while points below or left of the curve
indicate areas of underdamped performance.

and C

form a low pass network at the output, thus limiting

system bandwidth well below the amplifier bandwidth of
350MHz. By decreasing R

as C

increases (as illustrated in

the curves), the maximum bandwidth is obtained without
sacrificing stability. In spite of this, bandwidth decreases as
the load capacitance increases. For example, at A

= +2,

= 22

, C

= 100pF, the overall bandwidth is 125MHz, and

bandwidth drops to 100MHz at R

= 12

, C

= 220pF.

Evaluation Board

The performance of the HS-1412RH may be evaluated using
the HA5025 Evaluation Board, slightly modified as follows:

1. Remove the four feedback resistors, and leave the

connections open.

2. a. For A

= +1 evaluation, remove the gain setting

resistors (R

), and leave pins 2, 6, 9, and 13 floating.

b. For A

= +2, replace the gain setting resistors (R

) with

resistors to GND.

The modified schematic for amplifier 1, and the board layout
are shown in Figures 2 and 3.

To order evaluation boards (part number HA5025EVAL),
please contact your local sales office.

100

200

300

400

LOAD CAPACITANCE (pF)

SERIES OUTPUT RESIST

ANCE (

)

= +1

= +2

150

250

350

FIGURE 1. RECOMMENDED SERIES RESISTOR vs LOAD

CAPACITANCE

+5V

0.1

GND

-5V

0.1

OUT

= +1)

or 0

= +2)

NOTE: R

FIGURE 2. MODIFIED EVALUATION BOARD SCHEMATIC

(NOTE)

FIGURE 3A. TOP LAYOUT

FIGURE 3B. BOTTOM LAYOUT

FIGURE 3. EVALUATION BOARD LAYOUT

HS-1412RH

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified

FIGURE 4. SMALL SIGNAL PULSE RESPONSE

FIGURE 5. LARGE SIGNAL PULSE RESPONSE

FIGURE 6. SMALL SIGNAL PULSE RESPONSE

FIGURE 7. LARGE SIGNAL PULSE RESPONSE

FIGURE 8. SMALL SIGNAL PULSE RESPONSE

FIGURE 9. LARGE SIGNAL PULSE RESPONSE

= +2

200

150

100

-50

-100

-150

-200

OUTPUT V

GE (mV)

TIME (5ns/DIV.)

= +2

2.0

1.5

1.0

0.5

-0.5

-1.0

-1.5

-2.0

OUTPUT V

GE (V)

TIME (5ns/DIV.)

= +1

200

150

100

-50

-100

-150

-200

OUTPUT V

GE (mV)

TIME (5ns/DIV.)

= +1

2.0

1.5

1.0

0.5

-0.5

-1.0

-1.5

-2.0

OUTPUT V

GE (V)

TIME (5ns/DIV.)

= -1

200

150

100

-50

-100

-150

-200

OUTPUT V

GE (mV)

TIME (5ns/DIV.)

= -1

2.0

1.5

1.0

0.5

-0.5

-1.0

-1.5

-2.0

OUTPUT V

GE (V)

TIME (5ns/DIV.)

HS-1412RH

FIGURE 10. FREQUENCY RESPONSE

FIGURE 11. FREQUENCY RESPONSE FOR VARIOUS LOAD

RESISTORS

FIGURE 12. FREQUENCY RESPONSE FOR VARIOUS LOAD

RESISTORS

FIGURE 13. FREQUENCY RESPONSE FOR VARIOUS LOAD

RESISTORS

FIGURE 14. FREQUENCY RESPONSE FOR VARIOUS OUTPUT

VOLTAGES

FIGURE 15. FREQUENCY RESPONSE FOR VARIOUS OUTPUT

VOLTAGES

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified (Continued)

= -1

= +1

= -1

= +1

GAIN

PHASE

OUT

= 200mV

P-P

= +2

0.3

100

500

-3

-6

270

180

NORMALIZED GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

GAIN

PHASE

= +2, V

OUT

= 200mV

P-P

0.3

100

500

270

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

= 1k

= 100

= 50

= 1k

= 100

= 50

GAIN

PHASE

= +1, V

OUT

= 200mV

P-P

0.3

100

500

-3

-6

270

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

= 1k

= 100

= 50

= 1k

= 100

= 50

GAIN

PHASE

= -1, V

OUT

= 200mV

P-P

0.3

100

500

-3

-6

-90

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

= 1k

=100

= 50

= 1k

= 100

= 50

GAIN

PHASE

= +2

0.3

100

500

270

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

P-P

2.5V

P-P

2.5V

P-P

360

GAIN

PHASE

= +1

0.3

100

500

-3

-6

270

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

P-P

2.5V

P-P

360

2.5V

P-P

HS-1412RH

FIGURE 16. FREQUENCY RESPONSE FOR VARIOUS OUTPUT

VOLTAGES

FIGURE 17. FULL POWER BANDWIDTH

FIGURE 18. -3dB BANDWIDTH vs TEMPERATURE

FIGURE 19. GAIN FLATNESS

FIGURE 20. REVERSE ISOLATION (S

)

FIGURE 21. ALL HOSTILE CROSSTALK

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified (Continued)

GAIN

PHASE

= -1

0.3

100

500

-3

-6

-90

180

GAIN (dB)

PHASE (DEGREES)

FREQUENCY (MHz)

2.5V

P-P

2.5V

P-P

OUT

= 5V

P-P

0.3

100

500

-3

NORMALIZED GAIN (dB)

FREQUENCY (MHz)

= +2

= +1

= -1

-6

-9

-12

-15

-18

-21

200

250

300

350

400

450

TEMPERATURE (

AND

WIDTH (MHz)

-50

-25

100

125

= -1

= +1

= +2

100

0.4

0.3

0.2

0.1

NORMALIZED GAIN (dB)

FREQUENCY (MHz)

-0.1

-0.2

-0.3

-0.4

0.5

-0.5

OUT

= 200mV

P-P

= +2

= -1

= +1

200

0.3

100

500

-45

-50

-55

-60

GAIN (dB)

FREQUENCY (MHz)

= +2

= -1

= +1

-65

-70

-75

-80

-85

-90

-40

0.3

100

-10

-20

-30

-40

OSST

ALK (dB)

FREQUENCY (MHz)

-50

-60

-70

-80

-90

= 100

HS-1412RH

FIGURE 22. 2nd HARMONIC DISTORTION vs P

OUT

FIGURE 23. 3rd HARMONIC DISTORTION vs P

OUT

FIGURE 24. 2nd HARMONIC DISTORTION vs P

OUT

FIGURE 25. 3rd HARMONIC DISTORTION vs P

OUT

FIGURE 26. 2nd HARMONIC DISTORTION vs P

OUT

FIGURE 27. 3rd HARMONIC DISTORTION vs P

OUT

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified (Continued)

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= +2

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= +2

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= +1

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= +1

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= -1

-80

-75

-70

-65

-60

-55

-50

-45

-40

OUTPUT POWER (dBm)

DIST

TION (dBc)

-5

-2

20MHz

10MHz

= -1

HS-1412RH

FIGURE 28. OVERSHOOT vs TRANSITION TIME

FIGURE 29. OVERSHOOT vs TRANSITION TIME

FIGURE 30. OVERSHOOT vs TRANSITION TIME

FIGURE 31. OVERSHOOT vs TRANSITION TIME

FIGURE 32. INTEGRAL LINEARITY ERROR

FIGURE 33. SETTLING RESPONSE

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified (Continued)

INPUT TRANSITION TIME (ps)

VERSHOO

T (%)

100

500

900

1300

1700

2100

= -1

= +1

= +2

OUT

= +0.5V

INPUT TRANSITION TIME (ps)

VERSHOO

T (%)

100

500

900

1300

1700

2100

= -1

= +2

= +1

OUT

= +1V

INPUT TRANSITION TIME (ps)

VERSHOO

T (%)

100

500

900

1300

1700

2100

= -1

= +1

= +2

OUT

= 0.5V

P-P

INPUT TRANSITION TIME (ps)

VERSHOO

T (%)

100

500

900

1300

1700

2100

= -1

= +2

= +1

OUT

= 1V

P-P

-0.06

-0.05

-0.04

-0.03

-0.02

-0.01

0.01

0.02

INPUT VOLTAGE (V)

ERR

OR (%)

-1.5

-1.0

-0.5

0.5

1.0

1.5

= +2

= +1

= -1

= +2

0.2

0.1

SETTLING ERR

OR (%)

TIME (ns)

-0.05

-0.1

-0.2

0.05

HS-1412RH

FIGURE 34. SUPPLY CURRENT vs SUPPLY VOLTAGE

FIGURE 35. OUTPUT VOLTAGE vs TEMPERATURE

FIGURE 36. INPUT NOISE CHARACTERISTICS

Typical Performance Curves

SUPPLY

5V, T

= 25

C, R

= 100

, Unless Otherwise Specified (Continued)

SUPPLY VOLTAGE (

SUPPL

Y CURRENT (mA

/
AMPLIFIER)

4.5

6.5

5.5

5.6

5.7

5.8

5.9

6.0

6.1

6.2

6.3

6.4

6.5

6.6

3.6

3.5

3.4

3.3

3.2

3.1

2.9

2.8

2.7

2.6

-50

-25

100

125

TEMPERATURE (

OUTPUT V

GE (V)

3.0

OUT

= 50

)

|-V

OUT

| (R

= 50

)

OUT

= 100

)

|-V

OUT

| (R

= 100

)

= -1

0.1

100

FREQUENCY (kHz)

NOISE V

GE (nV/

Hz)

NOISE CURRENT (pA/

Hz)

HS-1412RH

All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certification.

Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time with-
out notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries 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 Intersil or its subsidiaries.

For information regarding Intersil Corporation and its products, see web site http://www.intersil.com

Burn-In Circuit

HS-1412RH CERDIP

NOTES:

1. R1 = 1k

5%, 1/4W [Per Socket].

2. C1 = C2 = 0.01

F [Per Socket] or 0.1

F (Per Row) Minimum.

3. D1 = D2 = 1N4002 or Equivalent [Per Board].

4. D3 = D4 = 1N4002 or Equivalent [Per Socket].

5. (-V) + (+V) = 11V

1.0V.

6. 20mA < (I

, I

) < 32mA.

7. -50mV < V

OUT

< +50mV.

Irradiation Circuit

HS-1412RH CERDIP

NOTES:

8. R1 = 1k

9. C1 = 0.1

10. V+ = +5.0V

0.5V

11. V- = -5.0V

0.5V

V+

V-

V+

V-

HS-1412RH

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ÐÐ»ÐµÐºÑ‚Ñ€Ð¾Ð½Ð½Ñ‹Ð¹ ÐºÐ¾Ð¼Ð¿Ð¾Ð½ÐµÐ½Ñ‚: HS1-1412RH-Q