NSC LM2698MM-ADJ

LM2698
SIMPLE SWITCHER ® 1.35A Boost Regulator
General Description
Features
The LM2698 is a general purpose PWM boost converter.
The 1.9A, 18V, 0.2ohm internal switch enables the LM2698
to provide efficient power conversion to outputs ranging from
2.2V to 17V. It can operate with input voltages as low as 2.2V
and as high as 12V. Current-mode architecture provides
superior line and load regulation and simple frequency compensation over the device’s 2.2V to 12V input voltage range.
The LM2698 sets the standard in power density and is
capable of supplying 12V at 400mA from a 5V input. The
LM2698 can also be used in flyback or SEPIC topologies.
The LM2698 SIMPLE SWITCHER ® features a pin selectable
switching frequency of either 600kHz or 1.25MHz. This promotes flexibility in component selection and filtering techniques. A shutdown pin is available to suspend the device
and decrease the quiescent current to 5µA. An external
compensation pin gives the user flexibility in setting frequency compensation, which makes possible the use of
small, low ESR ceramic capacitors at the output. Switchers
Made Simple ® software is available to insure a quick, easy
and guaranteed design. The LM2698 is available in a low
profile 8-lead MSOP package.
n
n
n
n
n
1.9A, 0.2Ω, internal switch (typical)
Operating voltage as low as 2.2V
600kHz/1.25MHz adjustable frequency operation
Switchers Made Simple ® software
8-Lead MSOP package
Applications
n
n
n
n
n
n
n
n
3.3V to 5V, 5V to 12V conversion
Distributed Power
Set-Top Boxes
DSL Modems
Diagnostic Medical Instrumentation
Boost Converters
Flyback Converters
SEPIC Converters
Typical Application Circuit
20012658
SIMPLE SWITCHER ® is a registered trademark of National Semiconductor Corporation.
© 2001 National Semiconductor Corporation
DS200126
www.national.com
LM2698 SIMPLE SWITCHER ® 1.35A Boost Regulator
October 2001
LM2698
Connection Diagram
Top View
20012604
8-Lead Plastic MSOP
NS Package Number MUA08A
Ordering Information
Order Number
Package Type
NSC Package
Drawing
Supplied As
Package ID
LM2698MM-ADJ
MSOP-8
MUA08A
1000 Units, Tape and Reel
S22B
LM2698MMX-ADJ
MSOP-8
MUA08A
3500 Units, Tape and Reel
S22B
Pin Description
Pin
Name
Function
1
VC
Compensation network connection. Connected to the output of the voltage error amplifier.
2
FB
Output voltage feedback input.
3
SHDN
4
GND
Analog and power ground.
5
VSW
Power switch input. Switch connected between SW pin and GND pin.
6
VIN
Analog power input.
7
FSLCT
8
NC
www.national.com
Shutdown control input, active low.
Switching frequency select input. VIN = 1.25MHz. Ground = 600kHz.
Connect to ground.
2
LM2698
Block Diagram
20012603
3
www.national.com
LM2698
Absolute Maximum Ratings
(Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
FB Voltage
−0.3V ≤ VFB ≤ 7V
VC Voltage
0.965 < VC < 1.565
SHDN Voltage
(Note 2)
−0.3V ≤ VSHDN ≤ 7V
FSLCT
(Note 2)
Operating Junction
Temperature Range
(Note 6)
−40˚C to +125˚C
Storage Temperature
−65˚C to +150˚C
Supply Voltage
Internally Limited
Lead Temperature
2kV
200V
Operating Conditions
150˚C
Power Dissipation (Note 3)
220˚C
Machine Model
−0.3V ≤ VFSLCT ≤ 12V
Maximum Junction
Temperature
Infrared (15 sec.)
Human Body Model
(Note 5)
−0.3V ≤ VSW ≤ 18V
SW Voltage
215˚C
ESD Susceptibility
(Note 4)
−0.3V ≤ VIN ≤ 12V
VIN
Vapor Phase (60 sec.)
2.2V to 12V
0 ≤ VSW ≤ 17.5V
SW Voltage
300˚C
Electrical Characteristics
Specifications in standard type face are for TJ = 25˚C and those with boldface type apply over the full Operating Temperature Range ( TJ = −40˚C to +125˚C)Unless otherwise specified. VIN =2.2V and IL = 0A, unless otherwise specified.
Symbol
IQ
Parameter
Quiescent Current
Conditions
Min
(Note 6)
FB = 0V (Not Switching)
VSHDN = 0V
VFB
Feedback Voltage
ICL
Switch Current Limit
VIN = 2.7V (Note 8)
%VFB/∆VIN
Feedback Voltage Line
Regulation
2.2V ≤ VIN ≤ 12.0V
IB
FB Pin Bias Current
(Note 9)
VIN
Input Voltage Range
2.2
gm
Error Amp Transconductance ∆I = 5µA
40
AV
Error Amp Voltage Gain
DMAX
Maximum Duty Cycle
FSLCT = Ground
DMIN
Minimum Duty Cycle
FSLCT = Ground
fS
Switching Frequency
ISHDN
Shutdown Pin Current
1.2285
1.35
Typ
(Note 7)
Max
(Note 6)
Units
1.3
2.0
mA
5
10
µA
1.26
1.2915
V
1.9
2.4
A
0.013
0.1
%/V
0.5
20
nA
12
V
135
290
µmho
120
78
FSLCT = VIN
V/V
85
%
15
%
30
FSLCT = Ground
FSLCT = VIN
480
600
720
kHz
1
1.25
1.5
MHz
VSHDN = VIN
0.01
0.1
µA
VSHDN = 0V
−0.5
-1
IL
Switch Leakage Current
VSW = 18V
0.01
3
µA
RDS(ON)
Switch RDS(ON)
VIN = 2.7V, ISW = 1A
0.2
0.4
Ω
THSHDN
SHDN Threshold Voltage
Output High
0.6
0.9
V
Output Low
UVP
www.national.com
0.3
0.6
On Threshold
1.95
2.05
2.2
V
Off Threshold
1.85
1.95
2.1
V
4
V
(Continued)
Specifications in standard type face are for TJ = 25˚C and those with boldface type apply over the full Operating Temperature Range ( TJ = −40˚C to +125˚C)Unless otherwise specified. VIN =2.2V and IL = 0A, unless otherwise specified.
Symbol
θJA
Parameter
Thermal Resistance
Conditions
Min
(Note 6)
Typ
(Note 7)
Junction to Ambient
(Note 10)
235
Junction to Ambient
(Note 11)
225
Junction to Ambient
(Note 12)
220
Junction to Ambient
(Note 13)
200
Junction to Ambient
(Note 14)
195
Max
(Note 6)
Units
˚C/W
Note 1: Absolute maximum ratings are limits beyond which damage to the device may occur. Operating Ratings are conditions for which the device is intended to
be functional, but device parameter specifications may not be guaranteed. For guaranteed specifications and test conditions, see the Electrical Characteristics.
Note 2: Shutdown and voltage frequency select should not exceed VIN.
Note 3: The maximum allowable power dissipation is a function of the maximum junction temperature, TJ(MAX), the junction-to-ambient thermal resistance, θJA,
and the ambient temperature, TA. See the Electrical Characteristics table for the thermal resistance of various layouts. The maximum allowable power dissipation
at any ambient temperature is calculated using: PD (MAX) = (TJ(MAX) − TA)/θJA. Exceeding the maximum allowable power dissipation will cause excessive die
temperature, and the regulator will go into thermal shutdown.
Note 4: The human body model is a 100 pF capacitor discharged through a 1.5kΩ resistor into each pin. The machine model is a 200pF capacitor discharged
directly into each pin.
Note 5: ESD susceptibility using the human body model is 500V for VC.
Note 6: All limits guaranteed at room temperature (standard typeface) and at temperature extremes (bold typeface). All room temperature limits are 100% tested
or guaranteed through statistical analysis. All limits at temperature extremes are guaranteed via correlation using standard Statistical Quality Control (SQC) methods.
All limits are used to calculate Average Outgoing Quality Level (AOQL).
Note 7: Typical numbers are at 25˚C and represent the most likely norm.
Note 8: This is the switch current limit at 0% duty cycle. The switch current limit will change as a function of duty cycle. See Typical performance Characteristics
section for ICL vs. VIN
Note 9: Bias current flows into FB pin.
Note 10: Junction to ambient thermal resistance (no external heat sink) for the MSO8 package with minimal trace widths (0.010 inches) from the pins to the circuit.
See ’Scenario ’A’’ in the Power Dissipation section.
Note 11: Junction to ambient thermal resistance for the MSO8 package with minimal trace widths (0.010 inches) from the pins to the circuit and approximately
0.0191 sq. in. of copper heat sinking. See ’Scenario ’B’’ in the Power Dissipation section.
Note 12: Junction to ambient thermal resistance for the MSO8 package with minimal trace widths (0.010 inches) from the pins to the circuit and approximately
0.0465 sq. in. of copper heat sinking. See ’Scenario ’C’’ in the Power Dissipation section.
Note 13: Junction to ambient thermal resistance for the MSO8 package with minimal trace widths (0.010 inches) from the pins to the circuit and approximately
0.2523 sq. in. of copper heat sinking. See ’Scenario ’D’’ in the Power Dissipation section.
Note 14: Junction to ambient thermal resistance for the MSO8 package with minimal trace widths (0.010 inches) from the pins to the circuit and approximately
0.0098 sq. in. of copper heat sinking on the top layer and 0.0760 sq. in. of copper heat sinking on the bottom layer, with three 0.020 in. vias connecting the planes.
See ’Scenario ’E’’ in the Power Dissipation section.
5
www.national.com
LM2698
Electrical Characteristics
LM2698
Typical Performance Characteristics
Efficiency vs Load Current
(VOUT = 8V, fS = 600kHz)
Efficiency vs Load Current
(VOUT = 8V, fS = 1.25MHz)
20012667
20012666
Iq vs VIN (600 kHz, non-switching)
Iq vs VIN (600 kHz, switching)
20012619
20012618
Iq vs. VIN (1.25MHz, non-switching)
Iq vs VIN (1.25MHz, switching)
20012617
20012622
www.national.com
6
LM2698
Typical Performance Characteristics
(Continued)
Iq(SHDN) vs VIN
RDS(ON) vs VIN
20012616
20012621
Switching Frequency vs VIN (600kHz)
Switching Frequency vs VIN (1.25MHz)
20012620
20012623
ICL vs. Ambient Temperature
VIN = 3.3V, VOUT = 8V
ICL vs. VIN
20012641
20012642
7
www.national.com
LM2698
Operation
Continuous Conduction Mode
20012602
FIGURE 1. Simplified Boost Converter Diagram
(a) First Cycle of Operation (b) Second Cycle Of Operation
The LM2698 is a current-mode, PWM boost regulator. A
boost regulator steps the input voltage up to a higher output
voltage. In continuous conduction mode (when the inductor
current never reaches zero at steady state), the boost regulator operates in two cycles.
In the first cycle of operation, shown in Figure 1 (a), the
transistor is closed and the diode is reverse biased. Energy
is collected in the inductor and the load current is supplied by
COUT.
The second cycle is shown in Figure 1 (b). During this cycle,
the transistor is open and the diode is forward biased. The
energy stored in the inductor is transferred to the load and
output capacitor.
The ratio of these two cycles determines the output voltage.
The output voltage is defined as:
Inductor
where D is the duty cycle of the switch.
20012605
FIGURE 2. (a) Inductor Current (b) Diode Current
The inductor is one of the two energy storage elements in a
boost converter. Figure 2 shows how the inductor current
varies during a switching cycle. The current through an
inductor is quantified as:
www.national.com
8
Current Limit
(Continued)
The current limit in the LM2698 is referenced to the peak
switch current. The peak currents in the switch of a boost
converter will always be higher than the average current
supplied to the load. To determine the maximum average
output current that the LM2698 can supply, use:
IOUT(MAX) = (ICL − ∆iL)*(1−D) = (ICL − ∆iL)*VIN/VOUT
If VL(t) is constant, diL / dt must be constant, thus the current
in the inductor changes at a constant rate. This is the case in
DC/DC converters since the voltages at the input and output
can be approximated as a constant. The current through the
inductor of the LM2698 boost converter is shown in Figure
2(a). The important quantities in determining a proper inductance value are IL(AVG) (the average inductor current) and ∆iL
(the inductor current ripple). If ∆iL is larger than IL(AVG), the
inductor current will drop to zero for a portion of the cycle and
the converter will operate in discontinuous conduction mode.
If ∆iL is smaller than IL(AVG), the inductor current will stay
above zero and the converter will operate in continuous
conduction mode (CCM). All the analysis in this datasheet
assumes operation in continuous conduction mode. To operate in CCM:
IL(AVG) > ∆iL
Where ICL is the switch current limit (see Electrical Charateristics table and Typical Performance Curves). Hence, as
VIN increases, the maximum current that can be supplied to
the load increases, as shown in Figure 3.
20012673
FIGURE 3. Maximum Output Current vs Input Voltage
Choose the minimum IOUT to determine the minimum L for
CCM operation. A common choice is to set ∆iL to 30% of
IL(AVG).
The inductance value will also affect the stability of the
converter. Because the LM2698 utilizes current mode control, the inductor value must be carefully chosen. See the
COMPENSATION section for recommended inductance values.
Choosing an appropriate core size for the inductor involves
calculating the average and peak currents expected through
the inductor. In a boost converter,
Diode
The diode in a boost converter such as the LM2698 acts as
a switch to the output. During the first cycle, when the
transistor is closed, the diode is reverse biased and current
is blocked; the load current is supplied by the output capacitor. In the second cycle, the transistor is open and the diode
is forward biased; the load current is supplied by the inductor.
Observation of the boost converter circuit shows that the
average current through the diode is the average load current, and the peak current through the diode is the peak
current through the inductor. The diode should be rated to
handle more than its peak current. To improve efficiency, a
low forward drop Schottky diode is recommended.
Input Capacitor
Due to the presence of an inductor at the input of a boost
converter, the input current waveform is continuous and
triangular. The inductor ensures that the input capacitor sees
fairly low ripple currents. However, as the inductor gets
smaller, the input ripple increases. The rms current in the
input capacitor is given by:
and
IL(Peak) = IL(AVG) + ∆iL,
where
A core size with ratings higher than these values should be
chosen. If the core is not properly rated, saturation will
dramatically reduce overall efficiency.
The input capacitor should be capable of handling the rms
current. Although the input capacitor is not so critical in boost
applications, a 10 µF or higher value, good quality capacitor
prevents any impedance interactions with the input supply.
A 0.1µF or 1µF ceramic bypass capacitor is also recommended on the VIN pin (pin 6) of the IC. This capacitor must
9
www.national.com
LM2698
Operation
LM2698
Operation
There is a minimum inductance requirement in any current
mode converter. This is a function of VOUT, duty cycle, and
switching frequency, among other things. The graphs below
plot the recommended inductance range vs. duty cycle for
VOUT = 12V. The two lines represent the upper and lower
bounds of the recommended inductance range. The simplified compensation procedure that follows assumes that the
inductance never drops below the Q = 5 line. Figure 4 plots
the equation:
(Continued)
be connected very close to pin 6 to effectively filter high
frequency noise. When operating at 1.25 MHz switching
frequency, a minimum bypass capacitance of 0.22 µF is
recommended.
Output Capacitor
The output capacitor in a boost converter provides all the
output current when the switch is closed and the inductor is
charging. As a result, it sees very large ripple currents. The
output capacitor should be capable of handling the maximum RMS current. The RMS current in the output capacitor
is:
(1)
where,
RDSON = 0.15,
Se = 0.072*fS,
and Q = 0.5 and 5
Use Q = 5 to calculate the minimum inductance recommended for a stable design. Choosing an inductor between
the Q = 0.5 and Q = 5 values provides a good tradeoff
between size and stability. Note that as VIN drops less than
5V, RDS(ON) increases, as shown in the Typical Performance
Characteristics section (RDS(ON) vs.VIN curve). The worst
case RDS(ON) should be used when choosing the inductance. To view plots for different Vout, multiply the Y axis by
a factor of VOUT/12, or plot Equation (1) for the respective
output voltage.
where,
and
D = (VOUT - VIN)/VOUT
The ESR and ESL of the output capacitor directly control the
output ripple. Use capacitors with low ESR and ESL at the
output for high efficiency and low ripple voltage. Surface
mount tantalums, surface mount polymer electrolytic, and
polymer tantalum, Sanyo OS-CON, or multi-layer ceramic
capacitors are recommended at the output.
Compensation
This section presents a step-by-step procedure to design the
compensation network at pin 1 (Vc) of the LM2698. These
design methods will produce a conservative and stable control loop.
20012654
20012653
FIGURE 4. Minimum Inductance Requirements for (a) fS = 600kHz and (b) fS = 1.25MHz
www.national.com
10
performance can be best analyzed by plotting the magnitude
and phase of the open loop frequency response in the form
of a bode plot. A typical bode plot of the LM2698 open loop
frequency response is shown in Figure 5.
(Continued)
The goal of the compensation network is to provide the best
static and dynamic performance while insuring stability over
line and load variations. The relationship of stability and
20012657
FIGURE 5. Bode plot of the LM2698 Frequency Response using the Typical Application Circuit
Poles are marked with an ’X’, and zeros are marked with a
’O’. The bolded ’O’ labeled ’fRHP’ is a right-half plane zero.
Right half plane zeros act like normal zeros to the magnitude
(+20dB/decade slope influence) and like poles to the phase
(−90˚ shift). Three curves are shown. The powerstage curve
is the frequency response of the powerstage, which includes
the switch, diode, inductor, output capacitor, and load. The
compensator curve is the frequency response of the compensator, which is the error amp combined with the compensation network. T is the product of the powerstage and the
compensator and is the complete open loop frequency response. The power stage response is fixed by line and load
constraints, while the compensator is set by the external
compensation network at pin 1. The compensator can be
designed in a few simple steps as follows.
Quick Compensator Design
Calculate:
where ROUT = 875kΩ
Choose CC1 = 4.7nF
Choose
where,
Where,
11
www.national.com
LM2698
Operation
LM2698
Operation
ever the loop phase margin will become progressively lower
as CC1 is decreased. When optimizing the loop gain for
transient response time, it is recommended to keep the
phase margin above 40˚.
(Continued)
If the output capacitor is of high ESR (0.1Ω or higher), it may
be necessary to use CC2. A rule of thumb is that if
1/(2πCOUTESR) (Hz) is lower than fS/2 (Hz), CC2 should be
used. Choose CC2 such that:
(RC + ROUT)(COUTESR) / (RCROUT) (F)
where ROUT = output impedance of the error amp (875 kΩ).
Improving Transient Response Time
The above compensator design provides a loop gain with
high phase margin for a large stability margin. The transient
response time of this loop is limited by the lower
mid-frequency gain necessary to achieve a high phase margin. If it is desired to increase the transient response time,
CC1 may be decreased. Decreasing CC1 by 2x, 4x, and 6x
will yield increasingly shorter transient response times, how-
www.national.com
12
ing table to determine if your design is stable. Remember to
use worst case conditions (VIN(MIN), ROUT(MIN), ROUT(MAX)).
(Continued)
Additional Comments on the Open Loop Frequency Response
The procedure used here to pick the compensation network
will provide a good starting point. In most cases, these
values will be sufficient for a stable design. It is always
recommended to check the design in a real test setup. This
is easy to do with the aid of a dynamic load. Set the high and
low load values to your system requirements and switch
between the two at about 1kHz. View the output voltage with
an oscilloscope using AC coupling, and zoom in enough to
see the waveform react to the load change. Use the follow-
Response
Conclusion
What to
Change
Underdamped,
weak attenuation
Nearing instability
Make CC1
larger
Underdamped,
strong attenuation
Stable
Nothing
Critically damped
Stable
Nothing
Overdamped
Stable
Nothing
Application Information
20012668
FIGURE 6. 3.3V to 10V Boost Converter
ing these values in for Equation (1), it is found that either a
10 µH (1.25MHz operation) or a 22 µH (600kHz operation) is
necessary for a stable design. The circuit is operated at
1.25MHz to allow for a smaller inductance. From the Compensator Design equations, RC is calculated to be 18.6kΩ,
and a 20kΩ resistor is used.
1.25MHz Boost Converter
Figure 6 shows the LM2698 boosting 3.3V to 10V at 300mA.
As discussed in the COMPENSATION section, the RDS(ON)
of the internal FET in the LM2698 raises as the input voltage
drops below 5V (see Typical Performance Characteristics).
The minimum input voltage for this application is 2.5V, at
which point the RDS(ON) is approximately 200mΩ. Substitut-
13
www.national.com
LM2698
Operation
LM2698
Application Information
(Continued)
20012631
FIGURE 7. 3.3V SEPIC Converter
3.3V SEPIC
The LM2698 can be used to implement a SEPIC technology.
The advantages of the SEPIC topology are that it can step
up or step down an input voltage, and it has low input current
ripple.
The conversion ratio for the SEPIC is :
I1 = IOUT(VOUT/VIN)
∆i1 = VIND/(2*L1*fs)
I2 = IOUT
∆i1 = VIND/(2*L2*fs)
The switch sees a maximum current of I1 + I2 + ∆i1 + ∆i2. If
L1 = L2 = L, the maximum switch current is given by:
IOUT(1 + VOUT/VIN) + VIND/(L*fs)
The maximum load current is limited by this relationship to
the switch current.
The polarity of CSEPIC will change between each cycle, so a
ceramic capacitor should be used here. A high quality, low
ESR capacitor will directly improve efficiency because all the
load current passes through CSEPIC.
CIN should be chosen using the same relationship as in the
boost converter (see the CIN section). CIN must be able to
provide the necessary RMS current.
where
D’ = 1−D
Solving for D yeilds:
To avoid subharmonic oscillations, it is recommended that
inductors L1 and L2 be the same inductance. Currents conducted by the inductors are:
www.national.com
14
LM2698
Application Information
(Continued)
20012643
FIGURE 8. Level-Shifted SEPIC Converter
Level-Shifted SEPIC
The circuit shown in Figure 8 is similar to the SEPIC shown
in Figure 7, except that it is level shifted to provide a negative
output voltage. This is achieved by connecting the ground of
the LM2698 to the output. The circuit analysis for the
level-shifted SEPIC is the same as the SEPIC. The voltage
at the input of the LM2698 will need to be clamped if the
absolute value of the output voltage plus the input voltage
exceeds 12V, the absolute maximum rating for the VIN pin.
The simplest way to do this is with a zener diode, as shown
in Figure 8. Likewise, if the FSLCT pin is pulled high to
operate at 1.25 MHz, its voltage must not exceed 12V. To
prevent any high frequency noise from entering the
LM2698’s internal circuitry, a high frequency bypass capacitor must be placed as close to pin 6 as possible. A good
choice for this capacitor is a 0.1µF ceramic capacitor.
20012611
Power Dissipation
The output power of the LM2698 is limited by its maximum
power dissipation. The maximum power dissipation is determined by the formula
PD = (Tjmax - TA)/θJA
where Tjmax is the maximum specified junction temperature
(125˚C), TA is the ambient temperature, and θJA is the thermal resistance of the package. θJA is dependant on the
layout of the board as shown below.
20012612
15
www.national.com
LM2698
Application Information
(Continued)
20012615
20012613
20012614
www.national.com
16
LM2698 SIMPLE SWITCHER ® 1.35A Boost Regulator
Physical Dimensions
inches (millimeters)
unless otherwise noted
8-Lead Plastic MSOP
NS Package Number MUA08A
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 AND GENERAL
COUNSEL 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.
National Semiconductor
Corporation
Americas
Email: [email protected]
www.national.com
National Semiconductor
Europe
Fax: +49 (0) 180-530 85 86
Email: [email protected]
Deutsch Tel: +49 (0) 69 9508 6208
English Tel: +44 (0) 870 24 0 2171
Français Tel: +33 (0) 1 41 91 8790
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.
National Semiconductor
Asia Pacific Customer
Response Group
Tel: 65-2544466
Fax: 65-2504466
Email: [email protected]
National Semiconductor
Japan Ltd.
Tel: 81-3-5639-7560
Fax: 81-3-5639-7507
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.