NSC CLC449AJE

N
CLC449
1.1GHz Ultra-Wideband Monolithic Op Amp
General Description
Features
The CLC449 is an ultra-high-speed monolithic op amp, with a typical -3dB bandwidth of 1.1GHz at a gain of +2. This wideband op
amp supports rise and fall times less than 1ns, settling time of 6ns
(to 0.2%) and slew rate of 2500V/µs. The CLC449 achieves 2nd
harmonic distortion of -68dBc at 5MHz at a low supply current of
only 12mA. These performance advantages have been achieved
through improvements in National’s proven current feedback
topology combined with a high-speed complementary bipolar
process.
■
The DC to 1.2GHz bandwidth of the CLC449 is suitable for many IF
and RF applications as a versatile op amp building block for replacement of AC coupled discrete designs. Operational amplifier
functions such as active filters, gain blocks, differentiation, addition,
subtraction and other signal conditioning functions take full
advantage of the CLC449’s unity-gain stable closed-loop
performance.
The CLC449 performance provides greater headroom for lower
frequency applications such as component video, high-resolution
workstation graphics, and LCD displays. The amplifier’s 0.1dB
gain flatness to beyond 200MHz, plus 0.8ns 2V rise and fall times
are ideal for improved time domain performance. In
addition, the 0.03%/0.02° differential gain/phase performance
allows system flexibility for handling standard NTSC and PAL
signals.
■
■
■
■
■
■
■
1.1GHz small-signal bandwidth (Av = +2)
2500V/µs slew rate
0.03%, 0.02° DG, DΦ
6ns settling time to 0.2%
3rd order intercept, 30dBm @ 70MHz
Dual ±5V or single 10V supply
High output current: 90mA
2.5dB noise figure
Applications
■
■
■
■
■
■
■
High performance RGB video
RF/IF amplifier
Instrumentation
Medical electronics
Active filters
High-speed A/D driver
High-speed D/A buffer
CLC449
1.1GHz Ultra-Wideband Monolithic Op Amp
June 1999
Frequency Response (Av = +2V/V)
In applications using high-speed flash A/D and D/A converters, the
CLC449 provides the necessary wide bandwidth (1.1GHz), settling
(6ns to 0.2%) and low distortion into 50Ω loads to improve SFDR.
Typical Application
120MSPS High-Speed Flash ADC Driver
Pinout
DIP & SOIC
© 1999 National Semiconductor Corporation
Printed in the U.S.A.
http://www.national.com
CLC449 Electrical Characteristics
PARAMETERS
CONDITIONS
TYP
CLC449
+25°
+25°
1100
500
200
380
380
360
0.5
0.5
0.5
0.05
0.02
0.05
0.05
0.05
0.05
1.1
1.1
1.1
18
2000
18
2000
18
2000
-63
-52
-44
-84
-73
-62
30
16
59
-48
40
77
-66
55
59
-48
40
75
-64
53
59
-48
40
75
-64
53
2.2
15
3
2.9
20.0
5.0
3
25
6
50
2
25
48
47
12
7
9
9
30
45
60
20
25
40
43
44
13.5
41
45
14
41
46
14
200
200
150
0.15
3.1
2.8
2.2
60
0.15
3.1
2.8
2.1
50
0.25
3.1
2.8
1.9
40
FREQUENCY DOMAIN RESPONSE
-3dB bandwidth
small signal
<0.2Vpp
large signal
<2Vpp
±0.1 dB bandwidth
<2Vpp
gain flatness
peaking
DC to 200MHz
rolloff
DC to 200MHz
linear phase deviation
<200MHz
differential gain
4.43MHz, RL=150Ω
differential phase
4.43MHz, RL=150Ω
TIME DOMAIN RESPONSE
rise and fall time
settling time to 0.2%
settling time to 0.1%
overshoot
slew rate
0
0.1
0.8
0.03
0.02
2V step
2V step
2V step
2V step
4V step
0.8
6
11
10
2500
DISTORTION AND NOISE RESPONSE
2nd harmonic distortion
2Vpp, 5MHz
2Vpp, 20MHz
2Vpp, 50MHz
3rd harmonic distortion
2Vpp, 5MHz
2Vpp, 20MHz
2Vpp, 50MHz
3rd order intercept
70MHz
1dB gain compression @ 50MHz
equivalent input noise
non-inverting voltage
1MHz
inverting current
1MHz
non-inverting current
1MHz
STATIC DC PERFORMANCE
input offset voltage
average drift
input bias current
average drift
input bias current
average drift
power supply rejection ratio
common-mode rejection ratio
supply current
Ω, Vcc = ±5V, RL = 100Ω
Ω; unless specified)
(Av = +2, Rf = 250Ω
non-inverting
inverting
DC
DC
RL= ∞
MISCELLANEOUS PERFORMANCE
input resistance
non-inverting
input capacitance
non-inverting
output resistance
closed loop
output voltage range
RL= ∞
RL=100Ω
input voltage range
common-mode
output current
400
1.3
0.1
3.3
2.9
2.4
80
MIN/MAX RATINGS
UNITS NOTES
0° to +70° -40° to +85°
MHz
MHz
MHz
dB
dB
deg
%
deg
ns
ns
ns
%
V/µs
dBc
dBc
dBc
dBc
dBc
dBc
dBm
dBm
nV/√Hz
pA/√Hz
pA/√Hz
mV
µV/°C
µA
nA/°C
µA
nA/°C
dB
dB
mA
A
A
A
A
A
kΩ
pF
Ω
V
V
V
mA
Min/max ratings are based on product characterization and simulation. Individual parameters are tested as noted. Outgoing quality levels are
determined from tested parameters.
Notes
Absolute Maximum Ratings
Voc
Iout is short circuit protected to ground
common-mode input voltage
maximum junction temperature
operating temperature range
AJ
storage temperature range
lead temperature (soldering 10 sec)
ESD (human body model)
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±6V
A) J-level: spec is 100% tested at +25°C.
±Vcc
+150°C
Package Thermal Resistance
Package
-40°C to +85°C
-65°C to +150°C
+300°C
500V
Plastic (AJP)
Surface Mount (AJE)
2
θJC
θJA
90°C/W
110°C/W
105°C/W
130°C/W
0.1k
Rout (ohms)
0.1M
1k
1M
1M
10k
100k
1M
Frequency (Hz)
10M
10M
100M
10M
0.1M
Magnitude (0.1dB/div)
100k
D.G. (%), D.P. (deg)
Distortion (dBc)
10k
1M
10M
Time (1ns/div)
3
Phase (1deg/div)
-3dB Bandwidth (MHz)
Distortion (dBc)
20 log|Z| (dBΩ)
Intercept Point (dBm)
Distortion (dBc)
180
Magnitude (3dB/div)
Magnitude (3dB/div)
Magnitude (3dB/div)
Phase (deg)
160
Phase (deg)
Phase
(deg)
Noise Voltage (nV/√Hz), Current (pA/√Hz)
Phase (deg)
PSRR/CMRR (dB)
CLC449 Typical Performance Characteristics (TA = 25°C, Vcc = + 5V, Rf = 250Ω, Av = +2, RL = 100Ω)
Po = 10dBm
100M
100M
PSRR
100M
Time (1ns/div)
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CLC449 Typical Performance Characteristics (TA = 25°C, Vcc = + 5V, Rf = 250Ω, Av = +2, RL = 100Ω)
Input Offset Voltage, VIO (mV)
Magnitude (1dB/div)
Reverse Isolation (S12)
1.9
2.8
-10
1.8
2.6
-20
1.7
2.4
-30
1.6
2.2
1.5
2.0
1.4
1.3
1.2
-40
|S12| (dB)
VSWR
VSWR
Output VSWR
1.8
1.6
Uncompensated
Non-Inverting
1.2
Inverting
-50
-60
-70
1.4
1.1
Compensated
-80
1.0
1.0
-90
0.9
0.8
-100
0
100M
200M
300M
Frequency (Hz)
400M
500M
Rs (ohms)
Input Bias Current, IBI, IBN (µA)
Input VSWR
Settling Time (ns)
Gain Compression
0
100M
200M
300M
Frequency (Hz)
400M
500M
0
100M
200M
300M
Frequency (Hz)
400M
500M
CLC449 OPERATION
The normalized gain plots in the Typical Performance
Characteristics section show different feedback resistors,
Rf, for different gains. These values of Rf are recommended for obtaining the highest bandwidth with minimal
peaking. The resistor Rt in Figure 1 provides DC bias for
the non-inverting input.
CLC449 Extended Application Information
The following design and application topics will supply
you with:
• A comprehensive set of design parameters and
•
•
•
design parameter adjustment techniques.
A set of formulas that support design parameter
change prediction.
A series of common applications that the CLC449
supports.
A set of easy to use design guidelines for the
CLC449.
For Av ≤ 5, calculate the recommended Rf as follows:
Rf ≅ 340 - Av • Ri, where Ri = 45Ω. For Av > 5, the
minimum recommended feedback resistor is Rf = 100Ω.
Select Rg to set the DC gain: R g =
Additional design applications are possible with the
CLC449. If you have application questions, call 1-800-2729959 in the U.S. to contact a technical staff member.
Accuracy of DC gain is usually limited by the tolerance of
the external resistors Rf and Rg.
DC Gain (Non-Inverting)
The non-inverting DC voltage gain for the configuration
shown in Figure 1 is:
R
A V = 1+ f
Rg
DC Gain (Unity Gain Buffer)
Unity gain buffers are easily designed with a currentfeedback amplifier as long as the recommended feedback resistor Rf = 402Ω is used and Rg = ∞, i.e. open.
Parasitic capacitance at the inverting node may require a
slight increase of the feedback resistor Rf to maintain a
flat frequency response.
Vcc
3
Rt
+
7
CLC449
2
-
4
6
0.1µF
Vo
+
Vin
6.8µF
Rf
DC Gain (Inverting)
The inverting DC voltage gain for the configuration shown
in Figure 2 is:
Vee
Rg
+
0.1µF
6.8µF
Av = −
Figure 1: Non-Inverting Gain
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Rf
Av − 1
4
Rf
Rg
Vcc
higher than in non-inverting gains.
6.8µF
+
Rt
3
+
7
0.1µF
CLC449
2
Vin
Rg
-
4
DC Design (Level Shifting)
Figure 3 shows a DC level shifting circuit for inverting
gain configurations. Vref produces a DC output level shift
of
6
Vo
Rf
Rf
Rref
which is independent of the DC output produced by Vin.
Figure 3: Level Shifting Circuit
-Vref ⋅
0.1µF
+
6.8µF
Req1
Vee
Figure 2: Inverting Gain
The normalized gain plots in the Typical Performance
Characteristics section show different feedback resistors,
Rf, for different gains. These values of Rf are recommended
for obtaining the highest bandwidth with minimal peaking.
The resistor Rt in Figure 2 provides DC bias for the noninverting input.
Vin
Req2
Vref
Rref
+
Vo
CLC449
Rf
DC Design (Single Supply)
Figure 4 is a typical single-supply circuit. Resistors R1
and R2 form a voltage divider that sets the non-inverting
input DC voltage. This circuit has a DC gain of 1. The
coupling capacitor C1 isolates the DC bias point from the
previous stage. Both capacitors make a high pass
response; the high frequency gain is determined by Rf
and Rg.
For |Av| ≤ 4, calculate the recommended Rf as follows:
Rf ≅ 295 - |Av| • Ri, where Ri = 45Ω. For |Av| > 4, the
minimum recommended feedback resistor is Rf = 100 Ω.
Select Rg to set the DC gain:
Rf
Rg =
|
A
At large gains, Rg becomes small and
v | will load the
previous stage. This situation is resolved by driving
Rg with a low impedance buffer like the CLC111,
or increasing Rf and Rg (see the Bandwidth (Small
Signal) sub-section for the tradeoffs).
Vcc
Vcc
R1
Vin
+
C1
Accurate DC gain is usually limited by the tolerance of
the external resistors Rf and Rg.
Vo
CLC449
R2
Rf
Rg
Bandwidth (Small Signal)
The CLC449 current-feedback amplifier bandwidth is a
function of the feedback resistor (Rf), not of the DC voltage gain (Av). The bandwidth is approximately
proportional to 1/Rf. As a rule, if Rf doubles, the bandwidth is cut in half. Other AC specifications will also be
degraded. Decreasing Rf from the recommended
value increases peaking and for very small values of
Rf oscillation will occur.
C2
Figure 4: Single Supply Circuit
The complete gain equation for the circuit in Figure 4 is:

R 
1 + sτ 2 ⋅ 1 + f 
 Rg 
sτ1
Vo
=
⋅
Vin 1 + sτ1
1 + sτ 2
With an inverting amplifier design, peaking is sometimes
observed. This is often the result of layout parasitics
caused by inadequate ground planes or long traces. If
this is observed, placing a 50 to 200Ω resistor between
the non-inverting pin and ground will usually reduce the
peaking.
where s = jω, τ1 = (R1|| R2) • C1, and τ2 = RgC2.
DC Design (DC Offsets)
The DC offset model shown in Figure 5 is used to
calculate the output offset voltage. The equation for output offset voltage is:
Bandwidth (Minimum Slew Rate)
Slew rate influences the bandwidth for large signal
sinusoids. To determine an approximate value of slew
rate, necessary to support large sinusoids use the
following equation:

Rf 
Vo = − Vos + IBN ⋅ Req1 ⋅ 1 +
 + (IBI ⋅ R f )
 Req2 
(
)
The current offset terms, IBN and IBI, do not track each
other. The specifications are stated in terms of
magnitude only. Therefore, the terms Vos, IBN, and IBI
may have either positive or negative polarity. Matching
the equivalent resistance seen at both input pins does
not reduce the output offset voltage.
SR ≅ 5 • f • Vpeak
Vpeak is the peak output sinusoidal voltage, f is the
frequency of the sinusoid.
The slew rate of the CLC449 in inverting gains is always
5
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IBN
+
+
Vos
-
Req1
CLC449
-
IBI
Matching the output transmission line over greater
frequency ranges is accomplished by placing C6 in
parallel with R6, reducing the output impedance to
compensate for the internal increase of the op-amp’s output impedance with frequency.
Vo
RL
Rf
Thermal Design
To calculate the power dissipation for the CLC449,
follow these steps:
Req2
Figure 5: DC Offset Model
• Calculate the no-load op amp power:
Pamp = Icc • (Vcc – Vee)
DC Design (Output Loading)
RL, Rf, and Rg load the op amp output. The equivalent
closed-loop load impedance seen by the output in Figure
5 is:
• Calculate the output stage’s RMS power:
Po = (Vcc – Vload) • Iload
where Vload and Iload are the RMS voltage and
current across the external load.
• RL_eq = RL || (Rf + Req2), non-inverting gain
• RL_eq = RL || Rf, inverting gain
• Calculate the total op amp RMS power:
Pt = Pamp + Po
RL_eq needs to be kept large enough so that the
minimum available output current can produce the
required output voltage swing.
To calculate the maximum allowable ambient temperature, solve the following equation: Tamb = 175 – Pt • θJA,
where θJA is the thermal resistance from junction to
ambient in °C/W and Tamb is in °C. Thermal resistance
for the various packages are found in the Package
Thermal Resistance section.
Capacitive Loads
Capacitive loads, such as found in A/D converters,
require a series resistor (Rs) in the output to improve settling performance. The Rs and Settling Time vs. CL plot
in the Typical Performance Characteristics section
provides the information for selecting this resistor.
Also, use a series resistor to reduce the effects of
reactive loads on amplifier loop dynamics. For instance,
driving coaxial cables without an output series resistor
may cause peaking or oscillation.
Dynamic Range (Input /Output Protection)
Input ESD diodes are present on all connected pins for
protection from static voltage damage. For a signal that
may exceed the supply voltages, we recommend using
diode clamps at the amplifier’s input to limit the signals to
less than the supply voltages.
Transmission Line Matching
One method for matching the characteristic impedance of
a transmission line is to place the appropriate resistor at
the input or output of the amplifier. Figure 6 shows the
typical circuit configurations for matching transmission
lines.
Dynamic Range (Input /Output Levels)
The Electrical Characteristics section contains the
Common-Mode Input Range and Output Voltage
Range; these voltage ranges scale with the supplies.
Output Current is also specified in the Electrical
Characteristics section.
R1
Z0
V1 +-
R3
R2
R4
Z0
V2 +-
Rg
Unity gain applications are limited by the Common-Mode
Input Range. At greater non-inverting gains, the Output
Voltage Range becomes the limiting factor. Inverting gain
applications are limited by the Output Voltage Range.
C6
+
Z0
CLC449
-
R6
Vo
R7
Rf
For transimpedance or inverting gain applications, the
current (Iinv) injected at the inverting input pin of the op
amp needs to be:
V
|Iinv | ≤ max
Rf
R5
Figure 6: Transmission Line Matching
In non-inverting gain applications, Rg is connected directly
to ground.
The resistors R1, R2, R6, and R7
are equal to the characteristic impedance, Zo, of the
transmission line or cable.
where Vmax is the Output Voltage Range.
The voltage ranges discussed above are achieved as
long as the equivalent output load is large enough so that
the output current can produce the required output
voltage swing. See the DC Design (Output Loading)
sub-section for details.
In inverting gain applications, R3 is connected directly to
ground. The resistors R4, R6, and R7 are equal
to Zo. The parallel combination of R5 and Rg is also equal
to Zo.
Dynamic Range (Intermods)
For RF applications, the CLC449 specifies a third
order intercept of 30dBm at 70MHz and Po = 10dBm.
The input and output matching resistors attenuate the
signal by a factor of 2, therefore additional gain is needed.
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6
A 2-Tone, 3rd Order IMD Intercept plot is found in the
Typical Performance Characteristics section. The
output power level is taken at the load. Third-order
harmonic distortion is calculated with the formula:
The CLC449 noise model in Figure 8 is used to develop
the equation below.
The equation for Noise Figure (NF) is:
(
where:
• IP3o = third-order output intercept, dBm at
•
•
•
where:
the load.
Po = output power level, dBm at the load.
HD3 rd = third-order distortion from the
fundamental, -dBc.
dBm is the power in mW, at the load,
expressed in dB.
• Rs is the source resistance at the noninverting input.
• There is no matching resistor from the input
to ground.
• eni, ibn, ibi are the voltage and current noise
density terms (see in the Distortion and
Noise Response sub-section of the Electrical
Characteristics section).
• 4kT = 16 x 10-21J, T = 290°K.
• Rf is the feedback resistor and Rg is the gain
setting resistor.
Realized third-order output distortion is highly
dependent upon the external circuit. Some of the
common external circuit choices that improve 3rd order
distortion are:
• short and equal return paths from the load
to the supplies.
Printed Circuit Board Layout and Measurement
High Frequency op amp performance is strongly dependent on proper layout, proper resistive termination and
adequate power supply decoupling. The most important
layout points to follow are:
• de-coupling capacitors of the correct value.
• higher load resistance.
• a lower ratio of the output swing to the power
supply voltage.
Noise Figure (dB)
Dynamic Range (Noise)
In RF applications, noise is frequently specified as Noise
Figure (NF). Figure 7 plots NF for the CLC449 at a gain
of 10, with a feedback resistor Rf of 100Ω, and with no
input matching resistor. The minimum Noise Figure
(2.5dB) for these conditions occurs when the source
resistance equals 700Ω.
• Use a ground plane.
• Bypass power supply pins with monolithic
•
20
•
15
•
10
•
5
1000
100
capacitors of about 0.1µF value and place
the capacitors less than 0.1” (3mm) from the pin.
Bypass power supply pins with 6.8µF tantalum
capacitors for large signal current swings or
improved power supply noise rejection.
Minimize trace and lead lengths for components
between the inverting and output pins.
Remove ground plane underneath the
amplifier package and within 0.1” (3mm) of all
input/output pads.
If parts must be socketed, always use
flush-mount socket pins instead of high profile
sockets.
Evaluation boards are available for proto-typing and measurements.
Additional
layout
information
is
available in the evaluation board literature.
0
10
)
 e + i R 2 + 4kTR + i ⋅ R ||R 2 + 4kT ⋅ R ||R 
2
( bn s )
g
s
g
bi
f
f

NF = 10LOG  ni


4kTRs


HD3rd = 2 • (IP3o – Po)
10000
Source Resistance (Ω)
Figure 7. Noise Figure Plot
en
Rs
Vs
+
-
*
*
ibn
+
CLC449
Vo
-
Rf
*
ibi
Rg
Figure 8: CLC449 Noise Model
7
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CLC449 APPLICATIONS
achieve high differential bandwidth. For best high
frequency performance, maintain low parasitic capacitance from the diodes D1 and D2 to ground, and from the
input of the CLC522, to ground.
Low Noise Composite Amp With Input Matching
The composite circuit shown in Figure 9 eliminates the
need for a matching resistor to ground at the input. By
connecting two amplifiers in series, the first non-inverting and the second inverting, an overall inverting gain is
realized. The feedback resistor (Rf) connected from the
output of the second amplifier to the non-inverting input
of the first amplifier closes the loop, and generates a set
input resistance (Rin) that can be matched to Rs. This
resistor generates less noise than a matching resistor to
ground at the input.
Vin
3
Rin
50Ω
+
CLC449
6
2 -
Vs +-
Rf2
+
Rs
Rg2
CLC449
-
-
CLC449
Rf1
D1
250Ω
D2
Ro
50Ω
Vo
6
R2
50Ω
Figure 10: Full-Wave Rectifier
Flash A/D Application
The Typical Application circuit on the front page shows
the CLC449 driving a flash A/D. Flash A/D’s require fast
settling, low distortion, low noise and wide bandwidth to
achieve high Effective Number of Bits and Spurious Free
Dynamic Range (SFDR).
Input resistance and DC voltage gain of the amplifier are:
 R  R 
Rf
, where G = 1+ f1  ⋅  f2 
1+ G
 R g1   R g2 
 Rin 
Vo
= − G⋅

Vs
 Rin + R s 
This circuit connects a CLC449 to a TDA8716, 8-bit,
120MHz Flash Converter. The input capacitance for
this converter is typically 13pF plus layout capacitance.
From the Rs and Settling Time vs. CL plot in the
Typical Performance Characteristics section, select
a series resistor (Rs) of 55Ω. Place Rs in series with
the output of the CLC449 to achieve settling to 0.1% in
approximately 11ns.
Match the source resistance by setting: Rin = R s
Noise voltage produced by Rf, referred to the source Vs, is:


Rs
e 2R = 4kTRs ⋅ 

f
 Rin ⋅ (1 + G) 
The noise of a simple input matching resistor connected
to ground can be calculated by setting G to 0 in this
equation. Thus, this circuit reduces the thermal noise
produced by the matching resistor by a factor of (1+G).
Keep the amplifier noise seen at the A/D input at least
3dB lower than the A/D’s noise, to avoid degrading A/D
noise performance.
Ordering Information
Rectifier Circuit
Wide bandwidth rectifier circuits have many applications.
Figure 10 shows a 200MHz wideband full-wave rectifier
circuit using a CLC449 and CLC522 amplifier. Schottky or
PIN diodes are used for D1 and D2. They produce an
active half-wave rectifier whose signals are taken at the
feedback diode connection. The CLC522 takes the
difference of the two half-wave rectified signal, producing
a full-wave rectifier. The CLC522 is used at a gain of 5 to
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2
+
12
Rg 4
10
CLC522
162Ω
5 9
+
Figure 9: Composite Amplifier
Rin =
R1
50Ω
20Ω
250Ω
Vo
20Ω
Rg1
Rf
800Ω
3
250Ω
Rf
Rin
Vg
500Ω
Model
Temperature Range
CLC449AJP
CLC449AJE
CLC449AMC
-40°C to +85°C
-40°C to +85°C
-55°C to +125°C
Description
8-pin PDIP
8-pin SOIC
dice, MIL-STD-883
Contact factory for other packages and DESC SMD number.
Reliability Information
Transistor count
8
26
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CLC449
1.1GHz Ultra-Wideband Monolithic Op Amp
Customer Design Applications Support
National Semiconductor is committed to design excellence. For sales, literature and technical support, call the
National Semiconductor Customer Response Group at 1-800-272-9959 or fax 1-800-737-7018.
Life Support Policy
National’s products are not authorized for use as critical components in life support devices or systems without the express written approval of
the president of National Semiconductor Corporation. As used herein:
1. Life support devices or systems are devices or systems which, a) are intended for surgical implant into the body, or b) support or
sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can
be reasonably expected to result in a significant injury to the user.
2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to
cause the failure of the life support device or system, or to affect its safety or effectiveness.
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National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said
circuitry and specifications.
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