NSC LM3880MFE-1AD Power sequencer Datasheet

LM3880/LM3880Q
Power Sequencer
General Description
Features
The LM3880 Power Sequencer offers the easiest method to
control power up and power down of multiple power supplies
(switchers or linear regulators). By staggering the startup sequence, it is possible to avoid latch conditions or large in-rush
currents that can affect the reliability of the system.
Available in a SOT23-6 package, the Power Sequencer contains a precision enable pin and three open drain output flags.
Upon enabling the LM3880 the three output flags will sequentially release, after individual time delays, permitting the connected power supplies to startup. The output flags will follow
a reverse sequence during power down to avoid latch conditions.
EPROM capability allows every delay and sequence to be
fully adjustable. Contact National Semiconductor if a nonstandard configuration is required.
■
■
■
■
■
■
■
Easiest method to sequence rails
Power up and power down control
Input voltage range of 2.7V to 5.5V
Small footprint SOT23-6
Low quiescent current of 25 µA
Standard timing options available
Customization of timing and sequence available through
factory programmability
■ LM3880Q is AEC-Q100 Grade 1 qualified and is
manufactured on an Automotive Grade Flow
Applications
■
■
■
■
Multiple supply sequencing
Microprocessor / Microcontroller sequencing
FPGA sequencing
Automotive
Typical Application Circuit
20192601
© 2008 National Semiconductor Corporation
201926
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LM3880/LM3880Q Power Sequencer
May 1, 2008
LM3880/LM3880Q
Connection Diagram
20192602
Top View
SOT23–6 Package
Pin Descriptions
Pin #
Name
Function
1
VCC
Input supply
2
GND
Ground
3
EN
Precision enable pin
4
FLAG3
Open drain output #3
5
FLAG2
Open drain output #2
6
FLAG1
Open drain output #1
Nomenclature
20192603
Sequence Designator Table
Sequence Number
Flag Order
Power Up
Power Down
1
1-2-3
3-2-1
2
1-2-3
3-1-2
3
1-2-3
2-3-1
4
1-2-3
2-1-3
5
1-2-3
1-3-2
6
1-2-3
1-2-3
See timing diagrams for more information
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2
Timing
Designator
td1
td2
td3
td4
td5
td6
AE
2ms
2ms
2ms
2ms
2ms
2ms
AA
10ms
10ms
10ms
10ms
10ms
10ms
AB
30ms
30ms
30ms
30ms
30ms
30ms
AC
60ms
60ms
60ms
60ms
60ms
60ms
AD
120ms
120ms
120ms
120ms
120ms
120ms
See timing diagrams for more information
LM3880 Ordering Information
Standard Parts for Order*
Order
Number
Timer settings
td1 to td6
Sequence
Order
Supplied As
Package
Type
NSC Package
Drawing
Package
Marking
LM3880MF-1AE
2ms
1
1k units T&R
SOT23-6
MF06A
F25A
LM3880MFX-1AE
2ms
1
3k units T&R
SOT23-6
MF06A
F25A
LM3880MFE-1AE
2ms
1
250 units T&R SOT23-6
MF06A
F25A
LM3880MF-1AA
10ms
1
1k units T&R
SOT23-6
MF06A
F20A
LM3880MFX-1AA
10ms
1
3k units T&R
SOT23-6
MF06A
F20A
LM3880MFE-1AA
10ms
1
250 units T&R SOT23-6
MF06A
F20A
LM3880MF-1AB
30ms
1
1k units T&R
SOT23-6
MF06A
F21A
LM3880MFX-1AB
30ms
1
3k units T&R
SOT23-6
MF06A
F21A
LM3880MFE-1AB
30ms
1
250 units T&R SOT23-6
MF06A
F21A
LM3880MF-1AC
60ms
1
1k units T&R
SOT23-6
MF06A
F22A
LM3880MFX-1AC
60ms
1
3k units T&R
SOT23-6
MF06A
F22A
LM3880MFE-1AC
60ms
1
250 units T&R SOT23-6
MF06A
F22A
LM3880MF-1AD
120ms
1
1k units T&R
SOT23-6
MF06A
F23A
LM3880MFX-1AD
120ms
1
3k units T&R
SOT23-6
MF06A
F23A
LM3880MFE-1AD
120ms
1
250 units T&R SOT23-6
MF06A
F23A
LM3880QMFE-1AE
2ms
1
250 units T&R SOT23-6
MF06A
F24A
LM3880QMF-1AE
2ms
1
1k units T&R
SOT23-6
MF06A
F24A
LM3880QMFX-1AE
2ms
1
3k units T&R
SOT23-6
MF06A
F24A
LM3880QMFE-1AA
10ms
1
250 units T&R SOT23-6
MF06A
F27A
LM3880QMF-1AA
10ms
1
1k units T&R
SOT23-6
MF06A
F27A
LM3880QMFX-1AA
10ms
1
3k units T&R
SOT23-6
MF06A
F27A
LM3880QMFE-1AB
30ms
1
250 units T&R SOT23-6
MF06A
F28A
LM3880QMF-1AB
30ms
1
1k units T&R
SOT23-6
MF06A
F28A
LM3880QMFX-1AB
30ms
1
3k units T&R
SOT23-6
MF06A
F28A
LM3880QMFE-1AC
60ms
1
250 units T&R SOT23-6
MF06A
F29A
LM3880QMF-1AC
60ms
1
1k units T&R
SOT23-6
MF06A
F29A
LM3880QMFX-1AC
60ms
1
3k units T&R
SOT23-6
MF06A
F29A
LM3880QMFE-1AD
120ms
1
250 units T&R SOT23-6
MF06A
F30A
LM3880QMF-1AD
120ms
1
1k units T&R
SOT23-6
MF06A
F30A
LM3880QMFX-1AD
120ms
1
3k units T&R
SOT23-6
MF06A
F30A
Feature
AEC-Q100
Grade 1
qualified.
Automotive
Grade
Production
Flow**
*Non-standard parts are available upon request. Please contact National Semiconductor for more information.
**Automotive Grade (Q) product incorporates enhanced manufacturing and support processes for the automotive market, including defect detection
methodologies. Reliability qualification is compliant with the requirements and temperature grades defined in the AEC-Q100 standard. Automotive grade products
are identified with the letter Q. For more information go to http://www.national.com/automotive.
3
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LM3880/LM3880Q
Timing Designator Table
LM3880/LM3880Q
Operating Ratings
Absolute Maximum Ratings (Note 1)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
VCC
EN, FLAG1, FLAG2, FLAG3
Max Flag 'ON' Current
Storage Temperature Range
Junction Temperature
Lead Temperature (Soldering, 5
sec.)
Minimum ESD Rating
(Note 1)
VCC to GND
EN, FLAG1, FLAG2, FLAG3
Junction Temperature
2.7V to 5.5V
−0.3V to VCC + 0.3V
−40°C to +125°C
−0.3V to +6.0V
−0.3V to 6.0V
50 mA
−65°C to +150°C
150°C
260°C
±2 kV
Electrical Characteristics Specifications with standard typeface are for TJ = 25°C, and those in bold face type
apply over the full Operating Temperature Range (TJ = -40°C to +125°C). Minimum and Maximum limits are guaranteed through
test, design or statistical correlation. Typical values represent the most likely parametric norm at TJ = 25°C and are provided for
reference purposes only. VCC = 3.3V, and limits apply to all timing options, unless otherwise specified.
Symbol
IQ
Parameter
Conditions
Min
(Note 3)
Typ
(Note 4)
Max
(Note 3)
Unit
25
80
µA
1
20
nA
0.4
V
-15
15
%
-20
20
-15
15
-20
20
-15
15
-20
20
-15
15
-20
20
-15
15
-20
20
-15
15
2ms Timing Option
-20
20
For x = 1 or 4
95
105
For x = 1 or 4, 2ms option
90
110
For x = 2 or 5
95
105
For x = 2 or 5, 2ms option
90
110
Operating Quiescent current
Open Drain Flags
IFLAG
FLAGx Leakage Current
VFLAGx = 3.3V
VOL
FLAGx Output Voltage Low
IFLAGx = 1.2mA
Power Up Sequence
td1
Timer delay 1 accuracy
td2
Timer delay 2 accuracy
2ms Timing Option
2ms Timing Option
td3
Timer delay 3 accuracy
2ms Timing Option
%
%
Power Down Sequence
td4
Timer delay 4 accuracy
2ms Timing Option
td5
Timer delay 5 accuracy
td6
Timer delay 6 accuracy
2ms Timing Option
%
%
%
Timing Delay Error
(td(x) – 400 µs) / td(x+1) Ratio of timing delays
td(x) / td(x+1)
Ratio of timing delays
%
%
ENABLE Pin
VEN
EN pin threshold
IEN
EN pin pull-up current
1.0
VEN = 0V
1.25
7
1.4
V
µA
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but does not guarantee specific performance limits. For guaranteed specifications and conditions, see the Electrical Characteristics.
Note 2: The human body model is a 100 pF capacitor discharged through a 1.5 kΩ resistor into each pin.
Note 3: Limits are 100% production tested at 25°. Limits over the operating temperature range are guaranteed through correlation using Statistical Quality Control
(SQC) methods. The limits are used to calculate National's Average Outgoing Quality Level (AOQL).
Note 4: Typical numbers are at 25°C and represent the most likely parametric norm.
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4
Quiescent Current vs VCC
Quiescent Current vs Temperature (VCC = 3.3V)
20192605
20192604
Enable Threshold vs Temperature
Time Delay (30ms) vs VCC
20192606
20192607
Time Delay Ratio vs Temperature
Time Delay (30ms) vs Temperature
20192609
20192608
5
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LM3880/LM3880Q
Typical Performance Characteristics
LM3880/LM3880Q
FLAG VOL vs VCC
(RFLAG = 100 kΩ)
FLAG Voltage vs Current
20192611
20192610
Block Diagram
Block Diagram
20192612
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6
LM3880/LM3880Q
Timing Diagrams (Sequence 1)
All standard options use this sequence for output flags rise and fall order.
20192613
Power Up Sequence
20192614
Power Down Sequence
Application Information
appropriate delays. The three timers that are used to control
the power down scheme can also be individually programmed
and are completely independent of the power up timers.
Additional sequence patterns are also available in addition to
customizable timers. For more information see the custom
sequencer section.
OVERVIEW
The LM3880 Power Sequencer provides an easy solution for
sequencing multiple rails in a controlled manner. Six independent timers are integrated to control the timing sequence
(power up and power down) of three open drain output flags.
These flags permit connection to either a shutdown / enable
pin of linear regulators and switchers to control the power
supplies’ operation. This allows a complete power system to
be designed without worrying about large in-rush currents or
latch-up conditions that can occur.
The timing sequence of the LM3880 is controlled entirely by
the enable (EN) pin. Upon power up, all the flags are held low
until this precision enable is pulled high. After the EN pin is
asserted, the power up sequence will commence. An internal
counter will delay the first flag (FLAG1) from rising until a fixed
time period has expired. Upon the release of the first flag another timer will begin to delay the release of the second flag
(FLAG2). This process repeats until all three flags have sequentially been released. The three timers that control the
delays are all independent of each other and can be individually programmed if needed. (See custom sequencer section).
The power down sequence is the same as power-up, but in
reverse. When EN pin is de-asserted a timer will begin that
delays the third flag (FLAG3) from pulling low. The second
and first flag will then follow in a sequential manner after their
PART OPERATION
The timing sequence of the LM3880 is controlled by the assertion of the enable signal. The enable pin is designed with
an internal comparator, referenced to a bandgap voltage
(1.25V), to provide a precision threshold. This allows a delayed timing to be externally set using a capacitor or to start
the sequencing based on a certain event, such as a line voltage reaching 90% of nominal. For an additional delayed
sequence from the rail powering VCC, simply attach a capacitor to the EN pin as shown below.
7
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LM3880/LM3880Q
A resistor divider can also be used to enable the LM3880
based on a certain voltage threshold. Care needs to be taken
when sizing the resistor divider to include the effects of the
internal current source.
One of the features of the enable pin is that it provides glitch
free operation. The first timer will start counting at a rising
threshold, but will always reset if the enable pin is de-asserted
before the first output flag is released. This can be shown in
the timing diagram below:
20192615
Cap Timing
Using the internal pull-up current source to charge the external capacitor (CEN) the enable pin delay can be calculated by
the equation below:
20192617
EN Glitch
If the enable signal remains high for the entire power-up seWhen this event occurs, the falling edge of enable pin resets
quence, then the part will operate as shown in the standard
the current timer and will allow the remaining power-up cycle
timing diagrams. However, if the enable signal is de-asserted
to complete before beginning the power down sequence. The
before the power-up sequence is completed the part will enter
power down sequence starts approximately 120ms after the
a controlled shutdown. This allows the system to walk through
final power-up flag. This allows output voltages in the system
a controlled power cycling, preventing any latch conditions
to stabilize before everything is shutdown. An example of this
from occuring. This state only occurs if the enable pin is deoperation can be seen below:
asserted after the completion of timer 1, but before the entire
power-up sequence is completed.
20192618
Incomplete Sequence
All the internal timers are generated by a master clock that
mately 400 µs to timers 1 and 4 which is a result of the
has an extremely low tempco. This allows for tight accuracy
EPROM refresh. This refresh time is in addition to the proacross temperature and a consistent ratio between the indigrammed delay time and will be almost insignificant to all but
vidual timers. There is a slight additional delay of approxithe shortest of timer delays.
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8
Timer Options 1
Timer Options 2
Timer Options 3
Timer Options 4
0
0
0
0
2
4
6
8
4
8
12
16
6
12
18
24
8
16
24
32
10
20
30
40
12
24
36
48
14
28
42
56
16
32
48
64
18
36
54
72
20
40
60
80
22
44
66
88
24
48
72
96
26
52
78
104
28
56
84
112
30
60
90
120
All times listed are in milliseconds
The sequencing order for power up is always controlled by
layout. The flag number translates directly into the sequence
order during power up (ie FLAG1 will always be first). However, for some systems a different power down order could
be required. To allow flexibility for this aspect in a design, the
Power Sequencer incorporates six different options for controlling the power down sequence. These options can be seen
in the timing diagrams on the next page. This ability can be
programmed in addition to the custom timers.
9
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LM3880/LM3880Q
tity. Please contact National Semiconductor for more information.
The variables that can be programmed include the six delay
timers and the reverse sequence order. For the timers, each
can be individually selected from one of the timer selector
columns in the table shown below. However, all six time delays must be from the same column.
CUSTOM SEQUENCER
The LM3880 Power Sequencer is based on a CMOS process
utilizing an EPROM that has the capability to be custom programmed at the factory. Approximately 500,000,000 different
options are available allowing even the most complex system
to be simply sequenced. Because of the vast options that are
possible, customization is limited to orders of a certain quan-
LM3880/LM3880Q
20192619
Power Down Sequence Options
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10
LM3880/LM3880Q
Physical Dimensions inches (millimeters) unless otherwise noted
SOT23-6 Package
NS Package Number MF06A
11
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LM3880/LM3880Q Power Sequencer
Notes
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