ONSEMI MC10SX1130DR2G

MC10SX1130
LED Driver
Description
The MC10SX1130 is high speed LED Driver/current switch
specifically targeted for use in FDDI PMD and ANSI X3T9.3
FibreChannel 266 Mbits/s optical transmitters. The integrated circuit
contains several unique functional blocks which makes it easily
configurable for use with a variety of high performance LED devices.
The part is fabricated using MOSAIC III™ bipolar process. The logic
is designed so that a data HIGH input results in the modulation current
flowing through the IOUT pin to turn on the LED.
The device incorporates open collector outputs with a capability of
driving peak currents of 100 mA. Since the output current switching
circuitry simply switches current between the complementary outputs,
the dynamic switching demands on the system power supply are
greatly reduced. In addition, because the design is pure bipolar, the
device current drain is insensitive to the data pattern and frequency of
operation.
The LED drive current is adjustable through the selection of an
external set resistor, RSET. In addition, to allow for open loop
compensation for the LED’s negative optical output power tracking
over temperature, a circuit is included to provide an adjustable positive
temperature tracking coefficient to the LED drive current. This is
controlled through the selection of an external resistor, RTCO.
The MC10SX1130 incorporates novel pulse stretching circuitry
which is intended to compensate for the turn-on delay and rise and fall
time asymmetry inherent in LED devices. The stretch circuitry can be
used to pre-distort the input signal pulse width to minimize the duty
cycle distortion of the transmitted optical eye pattern. The stretch
circuitry supports three different selections of pre-distortion. This
choice is accomplished through a unique ‘tri-state’ input which can be
left open, tied to VCC, or tied to VEE to determine the pre-distortion
amount.
The device provides a VBB output for either single-ended use or as a
DC bias for AC coupling the signal into the device. The VBB pin
should only be used as a bias for the MC10SX1130 as its current
sink/source capability is limited. Whenever used, the VBB pin should
be bypassed to ground via a 0.01 mF capacitor.
Features
•
•
•
•
•
•
•
•
•
•
•
Differential Data Inputs
300 MHz Operation
100 mA Peak Drive Current
Extremely Low Jitter
Duty Cycle Distortion Compensation
Adjustable Output Current Tracking With Temperature
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LED DRIVER
SOIC−16
D SUFFIX
CASE 751B
MARKING DIAGRAM
10SX1130G
AWLYWW
A
WL
Y
WW
G
= Assembly Location
= Wafer Lot
= Year
= Work Week
= Pb−Free Package
ORDERING INFORMATION
See detailed ordering and shipping information in the package
dimensions section on page 8 of this data sheet.
Thermally Enhanced 16-Lead SOIC Package
75 kW Data Input Pulldown Resistors
+5 V or −5.2 V Operation
VBB Reference Available
Pb−Free Packages are Available*
*For additional information on our Pb−Free strategy and soldering details, please
download the ON Semiconductor Soldering and Mounting Techniques
Reference Manual, SOLDERRM/D.
© Semiconductor Components Industries, LLC, 2006
January, 2006 − Rev. 3
1
Publication Order Number:
MC10SX1130/D
MC10SX1130
VEE Stretch VEE
16
15
14
IOUT RSET IOUT
13
12
11
VCC
VEE
10
9
Stretch
ECL
BUFFER
DIN
BIAS
CONTROL
VBB
1
2
3
4
VCC
VBB
DIN
5
6
7
IOUT
PULSE WIDTH
ADJUST CIRCUIT
DIN
VEE
IOUT
8
DIN RTCO1 RTCO2 VEE
RTCO1
Figure 1. Pinout: SOIC−16
(Top View)
RTCO2
RSET
Figure 2. Block Diagram
Table 1. PIN FUNCTION TABLE
Pin
Function
DIN
Differential data inputs.
IOUT
Differential open collector outputs.
STRETCH
Control input to select the amount of duty cycle pre-distortion. When the pin is left open, no pre-distortion is
introduced. If the pin is connected to VCC, the output LOW state current pulse width is increased by 155 ps. When it
is connected to VEE, the current pulse width is increased by 310 ps.
RSET
Resistor to set LED drive current. This resistor sets the tail current of the output current switch and should be connected to the VEE plane. Since the RSET voltage compensation circuit is referenced to VEE, the RSET voltage will
track 1:1 with VEE changes, thus the voltage across the RSET resistor will remain constant.
RTCO1, RTCO2
Terminals for positive temperature tracking resistor. This resistor controls the temperature tracking rate of the voltage
at the RSET pin, which in turn sets the LED drive current tracking. If the two pins are shorted together, the nominal
tracking rate is 1.4mV/°C and when a 2 kW resistor is connected across the pins, the nominal tracking rate is
4.9 mV/°C.
VCC
Most positive power supply input. +5 V for PECL operation or ground for standard ECL operation.
VEE
Most negative power supply input. Ground for PECL operation or −5.2 V for standard ECL operation.
VBB
Reference voltage for use in single ended applications or when the input signal is AC coupled into the device.
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MC10SX1130
10 W
SUPPLY
DECOUPLING
CAPACITORS
10 W
16
15
14
13
12
11
10
9
VEE
Stretch
VEE
IOUT
RSET
IOUT
VCC
VEE
VEE
VCC
VBB
DIN
DIN
RTCO1
1
2
3
4
5
6
PECL
BIAS
50 W
50 W
IN
RTCO2
7
+5.0 V
VEE
8
1 kW
PECL
BIAS
IN
Figure 3. Typical +5 V Applications Circuit
Table 2. ABSOLUTE MAXIMUM RATINGS
Symbol
Parameter
Value
Unit
VEE
Power Supply (VCC = 0 V)
−7.0 to 0
VDC
VI
Input Voltage (VCC = 0 V)
0 to −6.0
VDC
Iout
Output Current
100
110
mA
TA
Operating Temperature Range
−40 to +85
°C
VEE
Operating Range (VCC = 0)
−5.5 to −4.5
VDC
Continuous
Surge
Maximum ratings are those values beyond which device damage can occur. Maximum ratings applied to the device are individual stress limit
values (not normal operating conditions) and are not valid simultaneously. If these limits are exceeded, device functional operation is not implied,
damage may occur and reliability may be affected.
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MC10SX1130
Table 3. DC CHARACTERISTICS (RTCO = 1 kW ±5%, RSET = R at IOUT = R at IOUT = 10 W ±1%,
Unless Otherwise Noted)(Note 1)
-40°C
Symbol
Characteristic
Min
IIH
Input HIGH Current
(DIN, DIN Pins)
IIL
Input LOW Current
(DIN, DIN Pins)
0.5
ICC
Quiescent Supply Current
(No Load on RSET Pin)
12
VIH
Input HIGH Voltage
(Note 2)
VCC = 5.0V, VEE = GND
VCC = GND, VEE = -4.5 to
-5.5V
VIL
VBB
VSET
Input LOW Voltage
(Note 2)
VCC = 5.0V, VEE = GND
VCC = GND, VEE = -4.5 to
-5.5 V
Output Reference Voltage
(Note 2)
VCC = 5.0 V, VEE = GND
VCC = GND, VEE = -4.5 to
-5.5 V
IOoff
Output ‘OFF’ Current
(IOUT, IOUT Pins)
VTR
VSET Tracking (Note 4)
Short Between RTCO1
and RTCO2
1 kW Between RTCO1
and RTCO2
2 kW Between RTCO1
and RTCO2
Min
Typ
25°C
Max
0.5
17
24
Min
Typ
200
85°C
Max
0.5
12
17
24
Min
Typ
200
12
Max
Unit
200
mA
0.5
18
24
12
mA
19
24
mA
mV
3770
-1230
4110
-890
3830
-1170
4160
-840
3870
-1130
4190
-810
3940
-1060
4280
-720
mV
3050
-1950
3500
-1500
3050
-1950
3520
-1480
3520
-1480
3050
-1950
3050
-1950
3555
-1445
mV
3570
-1430
3700
-1300
3620
-1380
3730
-1270
3650
-1350
3750
-1250
3690
-1310
3810
-1190
mV
VCC = GND (Note 3)
RTCO = Short
VEE = −5.2 V
RTCO = 1 kW
RTCO = 2 kW
Output ‘ON’ Current
(IOUT, IOUT Pins)
Max
200
Output Voltage at RSET
Pin
VCC = 5.0 V
RTCO = Short
VEE = GND
RTCO = 1 kW
RTCO = 2 kW
IOon
Typ
0°C
600
635
610
690
770
775
430
230
515
355
570
470
650
550
730
630
855
845
-4400
-4365
-4390
-4310
-4230
-4225
-4570
-4770
-4485
-4645
-4430
-4530
-4350
-4450
-4270
-4370
-4145
-4155
30
75
30
75
50
30
75
50
30
50
100
mA
50
mA
mV/°C
1.4
1.4
1.4
1.4
3.4
3.4
3.4
3.4
4.9
4.9
4.9
4.9
NOTE: Device will meet the specifications after thermal equilibrium has been established when mounted in a test socket or printed circuit
board with maintained transverse airflow greater than 500 lfpm. Electrical parameters are guaranteed only over the declared
operating temperature range. Functional operation of the device exceeding these conditions is not implied. Device specification limit
values are applied individually under normal operating conditions and not valid simultaneously.
1. 10SX circuits are designed to meet the DC specifications shown in the table after thermal equilibrium has been established. The circuit is
mounted in a test socket or mounted on a printed circuit board and transverse air greater than 500 lfm is maintained.
2. Note that in PECL applications, VIH, VIL, VBB will vary 1:1 with the VCC supply.
3. VSET tracks 1:1 with the VEE supply to maintain the same voltage across the RSET resistor.
4. VTR tracking measures the rate of change of the VSET voltage over temperature.
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MC10SX1130
Table 4. AC CHARACTERISTICS (RTCO = 1 kW ±5%, RSET = R at IOUT = R at IOUT = 10 W ±1%, Unless Otherwise Noted) (Note 5)
−40°C
Characteristic
Symbol
Condition
Min
Typ
0 to 85°C
Max
Min
Typ
Max
Unit
1300
1300
1000
950
1400
1400
1800
1850
ns
tPLH,
tPHL
Propagation Delay
(Differential)
to Output
(Single−Ended)
tStretch
Propagation Delay Stretch = OPEN
Stretch = VCC
Stretch = VEE
(Note 6)
0
145
300
120
250
0
155
310
200
380
tr 10−90
tf 90−10
Rise Time
Fall Time
10% to 90%
90% to 10%
600
375
510
330
880
550
1260
860
ps
tr 20−80
tf 80−20
Rise Time
Fall Time
20% to 80%
80% to 20%
490
260
360
220
600
500
850
750
ps
Jitter
Jitter
(Note 7)
(Note 8)
9
10
BW
Bandwidth
tSKEW
Duty Cycle Skew
VPP
Minimum Input Swing
(Note 10)
150
VCMR
Common Mode Range
(Note 11)
−0.400
Square Wave Input
Pseudo Random Input
300
(Differential)
(Note 9)
400
300
±30
6
15
ps
400
MHz
±30
ps
150
See 7
−0.400
ps
mV
See 7
V
NOTE: Device will meet the specifications after thermal equilibrium has been established when mounted in a test socket or printed circuit
board with maintained transverse airflow greater than 500 lfpm. Electrical parameters are guaranteed only over the declared
operating temperature range. Functional operation of the device exceeding these conditions is not implied. Device specification limit
values are applied individually under normal operating conditions and not valid simultaneously.
5. 10SX circuits are designed to meet the AC specifications shown in the table after thermal equilibrium has been established. The circuit is
mounted in a test socket or mounted on a printed circuit board and transverse air greater than 500 lfm is maintained.
6. When the Stretch function is used, the output low pulse width is increased by the specified amount.
7. Test condition uses a 133 MHz 50% duty cycle signal.
8. Test condition uses a 266 Mbit/s input pseudo-random data stream (n = 23).
9. Duty cycle skew is the difference between tPLH and tPHL propagation delay through a device, Stretch input is left open.
10. Minimum input swing for which AC parameters are guaranteed.
11. The CMR range is referenced to the most positive side of the differential input signal. Normal operation is obtained if the HIGH level falls
within the specified range and the peak-to-peak voltage lies between VPP Min and 1.0 V. The lower end of the CMR range is dependent on
VEE and is equal to VEE + 3.5 V.
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MC10SX1130
APPLICATIONS INFORMATION
Introduction
The data input circuitry has been realized as a traditional
differential ECL line receiver. It can accept either
differential 100K or 10KH style ECL or PECL depending on
the supply voltage used. In addition, a VBB reference is
provided for use in single ended applications. This reference
is useful if the input signal must be AC coupled into the
device.
The pulse stretcher provides two choices of duty cycle
pre-distortion. It is controlled by the input STRETCH
signal. When the pin is left open, no pre-distortion is applied
to the input waveform. If the pin is strapped to the upper or
lower rail, then the output waveform low pulse width will be
increased. In a +5 V application, when the STRETCH pin is
tied to +5 V, the nominal pulse width increase is 155 ps and
when it is connected to 0 V, the nominal pulse width is
increased by 310 ps.
The bias control circuitry regulates the voltage supplied at
the RSET pin of the output current switch. In addition, it
implements a positive tracking circuit which provides open
loop temperature compensation for the LED’s negative
tracking coefficient. An external resistor connected between
the RTCO1 and RTCO2 is used to select the rate of voltage
change at the RSET pin.
The output current switch is the final stage in modulating
the LED. The emitter of the current source is pinned out so
that an external resistor can be used to set the modulation
current. This circuit is implemented using a fully differential
gate where both collectors are brought out. As the LED is
modulated on and off, the current switches from one
collector to another. This architecture minimizes the
switching noise inherent in some LED driver design
topologies where the modulation current is actually turned
on and off.
The MC10SX1130 is intended to be integrated into high
performance fiber optic modules or used stand-alone to
drive a packaged optical LED device. The wide frequency
response of the device allows it to be used to support a
variety of digital communication applications ranging from:
• OC1/3 SONET/SDH Links
• 100 MBit/s FDDI
• 155 MBit/s ATM
• 133/266 MBit/s FibreChannel
To support such wide ranging application areas, the LED
Driver incorporates a variety of unique features. These offer
designers added flexibility that could not previously be
realized in less integrated designs.
LED Characteristics
LED devices emit light when forward biased. The optical
power emitted by an LED is determined by the amount of
current flowing through the device. This relationship is a
relatively linear function of the current, until the device
saturates. In some ways, an LED device behaves much like
a traditional small signal silicon diode, although the forward
“ON” voltage of an LED is much larger and ranges from
1.0 V to 2.0 V. In addition, for a fixed amount of current, the
optical power from the LED will decrease if the device
junction temperature increases. Another behavior of most
LED devices is that they have unequal turn-on and turn-off
times. In developing an LED transmitter, the designer must
wrestle with all these behaviors to develop a product that
meets the design targets.
LED Driver
The MC10SX1130 LED Driver accepts a digital binary
data stream which is processed by the driver circuitry to
create a current waveform to modulate the LED device. The
LED Driver contains circuitry to program the modulation
current, pre-distort the input waveform to partially
compensate for the LED turn-on/turn-off delay, and
compensate for the negative optical output power tracking
co-efficient. The LED Driver operates from a +5 V supply
for PECL applications or a −5.2 V supply for traditional
ECL systems. For further information on PECL, please
consult “Designing with PECL Application Note”,
AN1406/D available from a ON Semiconductor
representative.
Design Considerations
Once the user has selected an LED, the driver circuitry
should be optimized to match the characteristics of the LED.
The three circuit blocks previously described allow the user
to control the pulse width adjustment, LED drive current and
temperature tracking rate. A very simple example may best
illustrate the design process steps.
An LED has been selected which has the desired optical
output power when modulated with a waveform of 65mA.
In addition, the LED has an output power tracking
coefficient of −0.5%/°C. Thus for every 1°C rise in the case
temperature of the LED, the output power will decrease by
0.5% of the nominal value. In addition, the LED forward
voltage is 1.5 V.
Circuit Blocks
Some of the key sub-circuits in the LED Driver are listed
below:
• Input Line Receiver
• Pulse Stretcher
• Bias Control Circuitry
• Output Current Switch
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MC10SX1130
Thermal Management
First, the RSET resistor must be chosen to set the desired
nominal modulation current based on the following
equation:
LED devices tend to require large amounts of current for
most efficient operation. This requirement is then translated
into the design of the LED Driver. When large modulation
currents are required, power dissipation becomes a critical
issue and the user must be concerned about the junction
temperature of the device. The following equation can be
used to estimate the junction temperature of a device in a
given environment:
RSET = VSET/IMOD (Equation 1)
The voltage at VSET is a function of the RTCO tracking
resistor, so the desired tracking rate (VTR) must also be
chosen. To determine this, the equation must be normalized
to correspond to how the LED has been specified.
Temp Co = VTR/VSET (Equation 2)
TJ = TA + PD * qJA (Equation 3)
The data sheet has three temperature tracking rates for
different values of the RTCO resistor. By using the VSET
values at 25°C and substituting those numbers into
Equation 2, normalized tracking rates can be calculated.
TJ
TA
PD
qJA
Junction Temperature
Ambient Temperature
Power Dissipation
Average Thermal Resistance
(Junction-Ambient)
A specially designed thermally enhanced leadframe has
been used to house the LED Driver. Below is a graph of the
average qJA plotted against air flow.
Table 5. Normalized Tracking at 25°C
RTCO
Tracking %/°C
Short
+0.20
1 KW
+0.52
2 KW
+0.89
110
To match the LED chosen, a 1 kW resistor can be used.
Now that this is known, the value of the voltage at the VSET
can be substituted into Equation 1 to determine the value of
RSET resistor which, for this example is 10 W.
The Stretch circuit can be used to compensate for the
turn-on/turn-off delay of the LED. The circuit has been
designed for ease of use so the pin is designed to be strapped
to one of the two power plane levels to select the
pre-distortion value. If no pre-distortion is desired, the pin
can be left open. In this +5 V example, the maximum amount
of pre-distortion is desired, so the STRETCH pin is
connected to ground.
In addition a resistor must be placed between IOUT and
VCC. In selecting this resistor, just as in the case of the RSET,
the resistor type should be chosen to dissipate the worst case
power and derated for the worst case temperature. As a rule
of thumb, the voltage drop across the resistor should match
the forward voltage across the diode. The voltage can be
larger to minimize the power dissipated on chip when the
LED is not ’ON’. Although, the voltage drop across this
resistor should not be greater than 2 V. For this example:
ΘJA ( °C/W)
100
80
70
VSET@85 °C
RSET
0
100
200
300
400
500
AIRFLOW (LFPM)
Figure 4. Typical qJA versus Airflow
The power dissipation of the device has two components;
the quiescent power drain related to the pre-drive circuitry,
and the power dissipated in the current switch when driving
the LED.
Pd = Pstatic + Pswitching
(Equation 4)
The power dissipated in the current switch is a function of
the IMOD current, the LED forward voltage, and the value
of RSET. For example in a +5 V application, the following
equations can be used:
R @ IOUT = VF/IMOD
IMOD(max) +
90
+ 855mV + 86mA
10W
Pstatic = VCC * ICC (Equation 5)
Pswitching = (VCC-VF-VSET)* IMOD (Equation 6)
R @ IOUT = 1.5V/86mA = 17W
Because of the positive tracking circuitry in the LED
driver, the modulation current will increase over
temperature. It is important to now go back and re-calculate
the numbers under the worst case environmental conditions
to ensure that operating conditions have not been exceeded.
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MC10SX1130
performance failure of the affected pin. With this
relationship between intermetallic formation and junction
temperature established, it is incumbent on the designer to
ensure that the junction temperature for which a device will
operate is consistent with the long term reliability goals of
the system.
Reliability studies were performed at elevated ambient
temperatures (125°C) from which an Arrhenius Equation,
relating junction temperature to bond failure, was
established. The application of this equation yields the table
of Table 6. This table relates the junction temperature of a
device in a plastic package to the continuous operating time
before 0.1% bond failure (1 failure per 1000 bonds)
The MC10SX1130 device is designed with chip power
levels that permit acceptable reliability levels, in most
systems, under the conventional 500 lfpm (2.5 m/s) airflow.
Now to calculate the dissipated power on the chip for a
nominal application.
=5V
VCC
VF
= 1.5 V
VSET
= 0.7 V
IMOD = 60 mA
ICC
= 18 mA
so:
Pd = 5 * 18 + (5 - 1.5 - 0.7) * 60
Pd = 258 mW
This number can be entered into Equation 3 along with the
environmental information to calculate the nominal
operating junction temperature.
Because of the open loop feedback control in the bias
control circuitry, the revised IMOD value must be determined
given the tracking rate chosen so that the power dissipation
can be re-calculated. For assessing product reliability, worst
case values should be entered to calculate the maximum
junction temperature.
T = 6.376 × 10 −9 e
11554.267
273.15 + TJ
Where:
T = Time to 0.1% bond failure
Reliability of Plastic Packages
Although today’s plastic packages are as reliable as
ceramic packages under most environmental conditions, as
the junction temperature increases a failure mode unique to
plastic packages becomes a significant factor in the long
term reliability of the device.
Modern plastic package assembly utilizes gold wire
bonded to aluminum bonding pads throughout the
electronics industry. As the temperature of the silicon
(junction temperature) increases, an intermetallic
compound forms between the gold and aluminum interface.
This intermetallic formation results in a significant increase
in the impedance of the wire bond and can lead to
Table 6. TJ vs Time to 0.1% Bond Failure
Junction
Temp. (°C)
Time (Hrs.)
Time (yrs.)
80
1,032,200
117.8
90
419,300
47.9
100
178,700
20.4
110
79,600
9.1
120
37,000
4.2
130
17,800
2.0
140
8,900
1.0
ORDERING INFORMATION
Package
Shipping †
MC10SX1130D
SOIC−16
48 Units / Rail
MC10SX1130DG
SOIC−16
(Pb−Free)
48 Units / Rail
MC10SX1130DR2
SOIC−16
2500 / Tape & Reel
MC10SX1130DR2G
SOIC−16
(Pb−Free)
2500 / Tape & Reel
Device
†For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging
Specifications Brochure, BRD8011/D.
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MC10SX1130
PACKAGE DIMENSIONS
SOIC−16
D SUFFIX
CASE 751B−05
ISSUE J
−A−
16
NOTES:
1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.
2. CONTROLLING DIMENSION: MILLIMETER.
3. DIMENSIONS A AND B DO NOT INCLUDE
MOLD PROTRUSION.
4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)
PER SIDE.
5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.127 (0.005) TOTAL
IN EXCESS OF THE D DIMENSION AT
MAXIMUM MATERIAL CONDITION.
9
−B−
1
P
8 PL
0.25 (0.010)
8
M
B
S
G
R
K
F
X 45 _
C
−T−
SEATING
PLANE
J
M
D
16 PL
0.25 (0.010)
M
T B
S
A
S
DIM
A
B
C
D
F
G
J
K
M
P
R
MILLIMETERS
MIN
MAX
9.80
10.00
3.80
4.00
1.35
1.75
0.35
0.49
0.40
1.25
1.27 BSC
0.19
0.25
0.10
0.25
0_
7_
5.80
6.20
0.25
0.50
INCHES
MIN
MAX
0.386
0.393
0.150
0.157
0.054
0.068
0.014
0.019
0.016
0.049
0.050 BSC
0.008
0.009
0.004
0.009
0_
7_
0.229
0.244
0.010
0.019
MOSAIC III is a trademark of Motorola, Inc.
ON Semiconductor and
are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice
to any products herein. SCILLC makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does SCILLC assume any liability
arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation special, consequential or incidental damages.
“Typical” parameters which may be provided in SCILLC data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All
operating parameters, including “Typicals” must be validated for each customer application by customer’s technical experts. SCILLC does not convey any license under its patent rights
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MC10SX1130/D