SPX3940U-3.3 [SIPEX]
1A Low Drop Out Voltage Regulator; 1A低压降稳压器
| 型号: | SPX3940U-3.3 |
| 厂家: | 
SIPEX CORPORATION |
| 描述: | 1A Low Drop Out Voltage Regulator |
| 文件: | 总7页 (文件大小:171K) |
| 中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
SPX3940/41/42
1A Low Drop Out Voltage Regulator
with Shutdown
(PRELIMINARY INFORMATION)
FEATURES
APPLICATIONS
• Output Accuracy 3.3V, @ 1A Output
• Very Low Quiescent Current
• Low Dropout Voltage
• Battery Powered Systems
• Cordless Telephones
• Radio Control Systems
• Portable/Palm Top/Notebook Computers
• Portable Consumer Equipment
• Portable Instrumentation
• Automotive Electronics
• SMPS Post-Regulator
• Extremely Tight Load And Line Regulation
• Very Low Temperature Coefficient
• Current & Thermal Limiting
• Error Flag Warns Of Output Dropout
• Voltage Reference
PRODUCT DESCRIPTION
The SPX3940/41/42 is a low power voltage regulator. This device is an excellent choice for battery-powered applications such as
cordless telephones, radio control systems and portable computers. The SPX3940/41/42 features very low quiescent current (100µA
Typ.) and very low dropout voltage. This includes a tight initial tolerance of 1% max and 2% max., and very low output temperature
coefficient, making the SPX3940/41/42 useful as a low-power voltage reference.
The error flag output feature is used as power-on reset for warning of a low output voltage, due to a falling voltage input of batteries.
Another feature is the logic-compatible shutdown input which enables the regulator to be switched on and off. The SPX3940/41/42 is
offered in 3-pin and 5-pin TO-220 package SOT-223, and surface mount TO-263 packages.
The regulator output voltage (of the 8-pin SO-8 and 5-pin TO-220 & TO-263) may be pin-strapped for a 3.3V or programmed from
1.24V to 29V with an external pair of resistors.
PIN CONNECTIONS
SOT-223 Package
TO-220 Package
SPX3940
TO-263-5 Package
SPX3941/42
TO-220-5 Package
VOUT
SPX3940
GND/ ADJ
VIN
1
2
3
Five Lead Package Pin Functions:
SPX3941/42
SPX3941
1) ERROR
INPUT
GND
SPX3942
ADJUST
GND/
ADJ
V
V
IN
OUT
Front View
SHUTDOWN
2)
3)
4)
5)
Front View
TO-252 Package
GND
OUTPUT
INPUT
1
2 3 4
5
TO-263Package
SHUTDOWN OUTPUT
Top View
1 2 3 4 5
3
2
1
VOUT
3
2
1
VOUT
Top View
ADJ/GND
VIN
GND/ ADJ
V IN
Front View
Front View
Rev. 12/19/00
SPX3940/41/42
ABSOLUTE MAXIMUM RATINGS
Power Dissipation..........................................Internally Limited
Lead Temp. (Soldering, 5 Seconds) ................................ 260°C
Storage Temperature Range ..............................-65° to +150°C
Operating Junction Temperature Range (Note 9)
Input Supply Voltage ...................................................+7.5V
Feedback Input Voltage ..................................-1.5V to +30V
Shutdown Input Voltage..................................-0.3V to +30V
Error Comparator Output................................-0.3V to +30V
ESD Rating ............................................................2KV Min
SPX3940/41/42...................................... -40C° to +125°C
ELECTRICAL CHARACTERISTICS at VS=±15V,TA=25°C, unless otherwise specified.
applies over the full
Boldface
operating temperature range.
PARAMETER
CONDITIONS
Typ.
SPX3940A
SPX3940/41
UNITS
Min
Max
Min
Max
(Note 2)
3.3V Version
Output Voltage
3.3
3.3
3.267
3.333
3.382
3.234
3.185
3.366
3.415
V
3.217
-40 C T +125 C
°
≤
≤
°
J
1mA ≤IL ≤ 1A
All Voltage Options
Output Voltage
20
ppm/°C
100
40
50
80
150
60
50
80
Temperature Coefficient
Line Regulation ( Note 3)
(Note 1)
20
35
mV
mV
6V ≤ VIN ≤30V (Note 4)
Load Regulation ( Note 3 )
IL = 50mA to 1mA
Output Noise Voltage
BV = 10Hz – 100kHz
µV(rms)
IL = 5mA
150
10
Ground Current
Current Limit
4.5V<Vin<5.5V
IL = 5mA
15
15
mA
20
20
Vin=5V
IL = 1A
VOUT = 0
200
250
200
250
110
1.7
1.2
1.2
A
Thermal Regulation
Dropout Voltage (Note 5)
0.05
0.5
0.2
0.2
%/w
V
IL = 1A
0.8
0.8
1.0
1.0
IL = 100mA
110
150
200
150
200
Typ
1.235
SPX3940/42
Adjustable Versions only
Reference Voltage
1.200
1.270
1.272
1.285
V
V
1.98
Reference Voltage
Over Temperature
(Note 6)
1.185
Feedback Pin Bias Current
20
50
60
80
nA
Reference Voltage
(Note 7)
ppm/°C
nA/°C
Temperature Coefficient
Feedback Pin Bias Current
Temperature Coefficient
0.1
Rev. 12/19/00
SPX3940/41/42
(Continued)
PARAMETER
Typ.
0.01
150
60
SPX3940/42
UNITS
CONDITIONS
(Note 2)
Min
Max
1.00
2.00
250
Output Leakage Current
Output Low Voltage
V
0H = 30V
µA
VIN = 4.5V
0L = 400µA
(Note 8)
(Note 8)
(Note 8)
mV
400
I
Upper Threshold Voltage
Lower Threshold Voltage
40
25
mV
75
95
mV
140
Hysteresis
Input logic Voltage
15
mV
V
Low (Regulator ON)
High (Regulator OFF)
1.3
30
2.0
0.7
90
Shut down Pin Input Current VS = 2.4V
VS = 30V
µA
150
800
1000
15
450
3
Regulator Output Current in
Shutdown
µA
25
Note 1: Output or reference voltage temperature coefficients defined as the worst case voltage change divided by the total temperature range.
Note 2: Unless otherwise specified all limits are guaranteed for Tj = 25°C, VIN = 6V, IL = 100µA and CL = 1µF. Additional conditions for the 8-pin versions are
feedback tied to 5V tap and output tied to output sense (VOUT = 5V) and VSHUTDOWN ≤ 0.8V.
Note 3: Regulation is measured at constant junction temperature, using pulse testing with a low duty cycle. Changes in output voltage due to heating effects are
covered under the specification for thermal regulation.
Note 4: Line regulation for the SPX3940/41/42 is tested at 150°C for IL = 1 mA. For IL = 100µA and TJ = 125°C, line regulation is guaranteed by design to 0.2%. See
typical performance characteristics for line regulation versus temperature and load current.
Note 5: Dropout voltage is defined as the input to output differential at which the output voltage drops 100 mV below its nominal value measured at 1V differential at
very low values of programmed output voltage, the minimum input supply voltage of 2V ( 2.3V over temperature) must be taken into account.
Note 6: VREF ≤VOUT ≤ (Vin - 1V), 2.3 ≤Vin≤30V, 100µA≤IL≤ 250 mA, TJ ≤ TJMAX
.
Note 7: Comparator thresholds are expressed in terms of a voltage differential at the feedback terminal below the nominal reference voltage measured at 6V input. To
express these thresholds in terms of output voltage change, multiply by the error amplifier gain = VOUT/VREF = (R1 + R2)/R2. For example, at a programmed output
voltage of 5V, the Error output is guaranteed to go low when the output drops by 95 mV x 5V/1.235 = 384 mV. Thresholds remain constant as a percent of VOUT as
V
OUT is varied, with the dropout warning occurring at typically 5% below nominal, 7.5% guaranteed.
Note 8: VSHUTDOWN ≥ 2V, VIN ≤ 30V, VOUT =0, Feedback pin tied to 5V Tap.
Note 9: The junction -to-ambient thermal resistance of the TO-92 package is 180°C/ W with 0.4” leads and 160°C/ W with 0.25” leads to a PC board.
The thermal resistance of the 8-Pin DIP package is 105°C/W junction-to-ambient when soldered directly to a PC board. Junction-to-ambient thermal resistance for the
SOIC (S) package is 160°C/W.
Rev. 12/19/00
SPX3940/41/42
APPLICATION HINTS
This problem can be fixed by adding a 100pF capacitor between
output and feedback and increasing the output capacitor to at least
3.3µF.
EXTERNAL CAPACITORS
The stability of the SPX3940/41/42 requires a 2.2µF or greater
capacitor between output and ground. Oscillation could occur
without this capacitor. Most types of tantalum or aluminum
electrolytic works fine here. For operations of below -25°C solid
tantalum is recommended since the many aluminum types have
electrolytes the freeze at about -30°C. The ESR of about 5Ω or
less and resonant frequency above 500kHz are the most
important parameters in the value of the capacitor. The capacitor
value can be increased without limit.
ERROR DETECTION COMPARATOR OUTPUT
The Comparator produces
a logic low output whenever the
SPX3940/41/42 output falls out of regulation by more than around
5%. This is around 60mV offset divided by the 1.235 reference
voltage. This trip level remains 5% below normal regardless of the
programmed output voltage of the regulator. Figure 1 shows the
timing diagram depicting the ERROR signal and the regulator output
voltage as the SPX3940/41/42 input is ramped up and down. The
ERROR signal becomes low at around 1.3V input, and goes high
around 5V input (input voltage at which Vout = 4.75). Since the
SPX3940/41/42’s dropout voltage is load dependent, the input voltage
trip point (around 5V) will vary with the load current. The output
voltage trip point (approx. 4.75V) does not vary with load.
At lower values of output current, less output capacitance is
required for stability. For the currents below 10mA the value of
the capacitor can be reduced to 0.5µF and 0.15µF for 1A. More
output capacitance needed for the 8-pin version at voltages below
5V since it runs the error amplifier at lower gain. At worst case
5µF or greater must be used for the condition of 250mA load at
1.23V output.
The error comparator has an open-collector output, which requires an
external pull-up resistor. Depending on the system requirements the
resistor may be returned to 5V output or other supply voltage. In
determining the value of this resistor, note that the output is rated to
sink 400µA, this value adds to battery drain in a low battery
condition. Suggested values range from 100K to 1MΩ. If the output
is unused this resistor is not required.
The SPX3940/41/42, unlike other low dropout regulators will
remain stable and in regulation with no load in addition to the
internal voltage divider. This feature is especially important in
application like CMOS RAM keep-alive. When setting the output
voltage of the SPX3940/41/42, a minimum load of 10mA is
recommended.
If there is more than 10 inches of wire between the input and the
AC filter capacitor or if a battery is used as the input then a 0.1µF
tantalum or aluminum electrolytic capacitor should be placed
from the input to the ground.
PROGRAMMING THE OUTPUT VOLTAGE OF
SPX3940/41/42
The SPX3940/41/42 may be pin-strapped for 5V using its internal
voltage divider by tying Pin 1 (output) to Pin 2 (sense) and Pin 7
(feedback) to Pin 6 (5V Tap).
Instability can occur if there is stray capacitance to the
SPX3940/41/42 feedback terminal (pin 7). This could cause
more problems when using a higher value of external resistors to
set the output voltage.
4.75V
O U T PU T
V O L TA G E
_______
ER R O R *
+
5.0V
+
IN PU T
V O L TA G E
+
1.3V
+
* See A pplication Info.
_______
F igure 1. E R R O R O utput T im ing
Rev. 12/19/00
SPX3940/41/42
Also, it may be programmed for any output voltage between its
1.235V reference and its 30V maximum rating. As seen in
Figure 2, an external pair of resistors is required.
Refer to the below equation for the programming of the output
voltage::
REDUCING OUTPUT NOISE
It may be an advantage to reduce the AC noise present at the output.
One way is to reduce the regulator bandwidth by increasing the size of
the output capacitor. This is the only way that noise can be reduced
on the 3 lead SPX3940/41/42 but is relatively inefficient, as
increasing the capacitor from 1µF to 220µF only decreases the noise
from 430µV to 160µV Vrms for a 100kHz bandwidth at 5V output.
Noise could also be reduced fourfold by a bypass capacitor across R1,
since it reduces the high frequency gain from 4 to unity. Pick
V
OUT = VREF × ( 1 + R1\ R2 )+ IFBR1
The VREF is 1.235 and IFB is the feedback bias current, nominally
-20nA. The minimum recommended load current of 1 µA forces
an upper limit of 1.2 MΩ on value of R2. If no load is presented
the IFB produces an error of typically 2% in VOUT, which may be
eliminated at room temperature by trimming R1. To improve the
accuracy choose the value of R2 = 100k this reduces the error by
0.17% and increases the resistor program current by 12µA. Since
the LP2951 typically draws 60 µA at no load with Pin 2 open-
circuited this is a small price to pay
C
BYPASS ≅ 1 / 2πR1 × 200 Hz
or choose 0.01µF. When doing this, the output capacitor must be
increased to 3.3µF to maintain stability. These changes reduce the
output noise from 430µV to 100µV Vrms for a 100kHz bandwidth at
5V output. With the bypass capacitor added, noise no longer scales
with output voltage so that improvements are more dramatic at higher
output voltages.
HEAT SINK REQUIREMENTS
Depending on the maximum ambient temperature and maximum
power dissipation a heat sink may be required with the
SPX3940/41/42. The junction temperature range has to be within
the range specified under Absolute Maximum Ratings under all
possible operating conditions. To find out if a heat sink is
required, the maximum power dissipation of the device needs to
be calculated. This is the maximum specific AC voltage that
must be taken into consideration at input. Figure 3 shows the
condition and power dissipation which should be calculated with
the following formula:
IIN
3.3V
VIN
IN
OUT
IL
P
TOTAL = (VIN - 5) IL + (VIN)IG
SPX3940
LOAD
+
+
Next step is to calculate the temperature rise TR (max). TJ (max)
maximum allowable junction temperature, TA (max) maximum
ambient temperature :
2.2 uF
GND
IG
IIN = IL + IG
TR (max) = TJ (max) - TA (max)
Junction to ambient thermal resistance θ(j-A) can be calculated
after determining of PTOTAL & TR (max):
Figure 3. 3.3V Regulator Circuit
θ(J-A) = TR (max)/P(max)
If the θ(J-A) is 60°C/W or higher, the device could be operated
without a heat sink. If the value is below 60°C/W then the heat
sink is required and the thermal resistance of the heat sink can be
calculated by the following formula, θ(J-C) junction to case, θ(C-H)
case to heat sink, θ(H-A) heat sink to ambient:
θ(J-A) = θ(J-C) + θ(C-H) + θ(H-A)
Rev. 12/19/00
SPX3940/41/42
TYPICAL APPLICATIONS
+VIN
+VIN
*V
= 3.3V
OUT
VOUT
SPX3940
+
10uF
GND
4
SPX3940 FIXED +3.3V REGULATOR
Rev. 12/19/00
SPX3940/41/42
ORDERING INFORMATION
Ordering No. Precision Output Voltage
Packages
1%
1%
1%
2%
2%
2%
1%
1%
1%
2%
2%
2%
1%
1%
1%
2%
2%
2%
1%
1%
1%
2%
2%
2%
2%
2%
2%
2%
2%
2%
2%
2%
2%
Adj
3.3V
5.0V
Adj
3 Lead SOT-223
3 Lead SOT-223
3 Lead SOT-223
3 Lead SOT-223
3 Lead SOT-223
3 Lead SOT-223
5 Lead TO-252
3 Lead TO-252
3 Lead TO-252
5 Lead TO-252
3 Lead TO-252
3 Lead TO-252
5 Lead TO-220
3 Lead TO-220
3 Lead TO-220
5 Lead TO-220
3 Lead TO-220
3 Lead TO-220
5 Lead TO-263
3 Lead TO-263
3 Lead TO-263
5 Lead TO-263
3 Lead TO-263
3 Lead TO-263
3 Lead TO-252
3 Lead TO-252
3 Lead TO-220
3 Lead TO-220
3 Lead TO-263
3 Lead TO-263
5 Lead TO-252
3 Lead TO-220
3 Lead TO-263
SPX3940AM3
SPX3940AM3-3.3
SPX3940AM3-5.0
SPX3940M3
3.3V
5.0V
Adj
SPX3940M3-3.3
SPX3940M3-5.0
SPX3940AR
3.3V
5.0V
Adj
SPX3940AR-3.3
SPX3940AR-5.0
SPX3940R
3.3V
5.0V
Adj
SPX3940R-3.3
SPX3940R-5.0
SPX3940AU
3.3V
5.0V
Adj
SPX3940AU-3.3
SPX3940AU-5.0
SPX3940U
3.3V
5.0V
Adj
SPX3940U-3.3
SPX3940U-5.0
SPX3940AT
3.3V
5.0V
Adj
SPX5940AT-3.3
SPX3940AT-5.0
SPX3940T
3.3V
5.0V
3.3V
5.0V
3.3V
5.0V
3.3V
5.0V
Adj
SPX3940T-3.3
SPX3940T-5.0
SPX3941R-3.3
SPX3941R-5.0
SPX3941U-3.3
SPX3941U-5.0
SPX3941T-3.3
SPX3941T-5.0
SPX3942R
Adj
SPX3942U
Adj
SPX3942T
Corporation
SIGNAL PROCESSING EXCELLENCE
Sipex Corporation
Headquarters and Main Offices:
22 Linnell Circle
Billerica, MA 01821
TEL: (978) 667-8700
FAX: (978) 670-9001
e-mail: sales@sipex.com
233 South Hillview Drive
Milpitas, CA 95035
TEL: (408) 935-7600
FAX: (408) 934-7500
Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the application or use of any product or circuit described
hereing; neither does it convey any license under its patent rights nor the rights of others.
Rev. 12/19/00
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