AD ZSPM4121

Data Sheet
Rev. 1.00 / April 2012
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
Brief Description
Features
The ZSPM4121 battery management load switch
can be used to protect a battery from excessive
discharge. It actively switches the battery power
source off if it drops to a set threshold (Off Mode).
When the input battery voltage is above the
threshold, the load switch is on (On Mode). The
ZSPM4121 threshold voltage (VTHRESH) is programmed at manufacturing to a set point in the
range of 1.2V to 4.2V with 100mV steps between
options.

When the input battery voltage has been switched
off by the ZSPM4121, the quiescent current draw on
the battery is in the order of 100pA (typical). The
quiescent current in the on state is as low as 70nA.
The ZSPM4121 consists of an internally generated
threshold voltage, a comparator with hysteresis,
slew rate control for the load switch, a P-channel
load switch, and an open-drain indicator pin. The
500mV hysteresis between the Off Mode and the On
Mode
prevents intermittent operation.
The
ZSPM4121 also provides over-current protection.







Power source is actively switched off when
VCC drops below a set threshold (programmed
at manufacturing)
Wide input voltage range: 1.2V to 5.5V
Threshold voltage options of 1.2V to 4.2V in
100mV steps (factory programmed)
Supervisory over-current limit shutdown
Low drop out disconnect from VCC to loads
Controlled turn-on slew rate
500mV Off Mode to On Mode hysteresis
Over current shutdown (3A)
Related ZMDI Smart Power Products

ZSPM4141 Ultra-Low-Power Linear Regulator
Available Support


Evaluation Kit
Support Documentation
Benefits
Physical Characteristics





Best-in-class ultra-low quiescent current in
Off Mode: 100pA (typical)
Ultra-low quiescent current in On Mode: 70nA
(typical)
Accurate on/off voltage threshold
Low Rds(on): 175mΩ (typical) @ 5V
Package: 8-pin DFN (2mm x 2mm)
ZSPM4121 Block Diagram
ZSPM4121
VCC
VOUT
Regulated
VTHRESH
NPG
GND
Note: At manufacturing, VTHRESH is programmed to a
customer-selected threshold voltage in the range of
1.2V to 4.2V with 100mV steps between options.
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner.
The information furnished in this publication is subject to changes without notice.
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
Typical Application Circuit for
Disconnecting the Battery
Typical Application Circuits:
Charger
Load
ZSPM4121
VOUT
VCC
NPG
GND
Typical Applications

Portable Batteries

Industrial

Medical

Smart cards

RFID
Typical Application Circuit for
Disconnecting the Load
ZSPM4121
Load
VOUT
Charger
VCC
NPG
GND
Ordering Information
Ordering Code*
Description
Package
ZSPM4121AI1W17
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 1.7V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W21
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.1V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W23
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.3V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W24
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.4V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W25
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.5V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W26
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.6V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W28
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.8V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W30
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 3.0V
8-pin DFN / 7” Reel (2500)
ZSPM4121KIT
ZSPM4121 Evaluation Kit
* X = W for 7” reel with 2500 parts or R for 13” reel with 3300. Custom VTHRESH values are also available: 1.2V to 4.2V (typical) in 100mV increments.
Sales and Further Information
www.zmdi.com
[email protected]
Zentrum Mikroelektronik
Dresden AG
Grenzstrasse 28
01109 Dresden
Germany
ZMD America, Inc.
1525 McCarthy Blvd., #212
Milpitas, CA 95035-7453
USA
Zentrum Mikroelektronik
Dresden AG, Japan Office
2nd Floor, Shinbashi Tokyu Bldg.
4-21-3, Shinbashi, Minato-ku
Tokyo, 105-0004
Japan
ZMD FAR EAST, Ltd.
3F, No. 51, Sec. 2,
Keelung Road
11052 Taipei
Taiwan
Zentrum Mikroelektronik
Dresden AG, Korean Office
POSCO Centre Building
West Tower, 11th Floor
892 Daechi, 4-Dong,
Kangnam-Gu
Seoul, 135-777
Korea
Phone +49 (0)351.8822
Fax
+49 (0)351.8822
Phone +855-ASK-ZMDI
(+855.275.9634)
Phone +81.3.6895.7410
Fax
+81.3.6895.7301
Phone +886.2.2377.8189
Fax
+886.2.2377.8199
Phone +82.2.559.0660
Fax
+82.2.559.0700
DISCLAIMER: This information applies to a product under development. Its characteristics and specifications are subject to change without notice. Zentrum Mikroelektronik Dresden AG
(ZMD AG) assumes no obligation regarding future manufacture unless otherwise agreed to in writing. The information furnished hereby is believed to be true and accurate. However, under
no circumstances shall ZMD AG be liable to any customer, licensee, or any other third party for any special, indirect, incidental, or consequential damages of any kind or nature whatsoever
arising out of or in any way related to the furnishing, performance, or use of this technical data. ZMD AG hereby expressly disclaims any liability of ZMD AG to any customer, licensee or
any other third party, and any such customer, licensee and any other third party hereby waives any liability of ZMD AG for any damages in connection with or arising out of the furnishing,
performance or use of this technical data, whether based on contract, warranty, tort (including negligence), strict liability, or otherwise.
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the prior written consent of the copyright owner.
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
Contents
1
ZSPM4121 Characteristics .................................................................................................................................. 6
1.1. Absolute Maximum Ratings .......................................................................................................................... 6
1.2. Thermal Characteristics ................................................................................................................................ 6
1.3. Recommended Operating Conditions .......................................................................................................... 6
1.4. Electrical Characteristics .............................................................................................................................. 7
2 Typical Performance Characteristics ................................................................................................................... 8
3 Description of Circuit ........................................................................................................................................... 9
4 Application Circuits ............................................................................................................................................ 10
4.1. Typical Application Circuits ......................................................................................................................... 10
5 Pin Configuration and Package ......................................................................................................................... 11
5.1. Package Dimensions and Marking Diagram .............................................................................................. 11
5.2. Pin Description for 8-Pin DFN (2x2 mm) .................................................................................................... 12
6 Layout and Soldering Requirements ................................................................................................................. 13
6.1. Recommended Landing Pattern for PCBs ................................................................................................. 13
6.2. Multi-Layer PCB Layout .............................................................................................................................. 14
6.3. Single-Layer PCB Layout ........................................................................................................................... 15
7 Ordering Information.......................................................................................................................................... 16
8 Related Documents ........................................................................................................................................... 16
9 Glossary ............................................................................................................................................................ 16
10 Document Revision History ............................................................................................................................... 17
List of Figures
Figure 2.1
Figure 2.2
Figure 2.3
Figure 2.4
Figure 2.5
Figure 2.6
Figure 3.1
Figure 4.1
Figure 4.2
Figure 5.1
Figure 5.2
Figure 6.1
Figure 6.2
Figure 6.3
Figure 6.4
Figure 6.5
On Mode / Off Mode Characteristics ..................................................................................................... 8
On Mode Switching Behavior ................................................................................................................ 8
On Mode / Off Mode Quiescent Current Iq ............................................................................................. 8
Off Mode VTHRESH Temperature Performance ........................................................................................ 8
On Mode / Off Mode Transition Delay ................................................................................................... 9
Over-Current Retry Performance ........................................................................................................... 9
ZSPM4121 Block Diagram..................................................................................................................... 9
Application Circuit for Disconnecting the Battery ................................................................................. 10
Application Circuit for Disconnecting the Load .................................................................................... 10
ZSPM4121 Package Drawing .............................................................................................................. 11
ZSPM4121 Pin Assignments (top view) .............................................................................................. 12
Recommended Landing Pattern for 8-Pin DFN ................................................................................... 13
Package and PCB Land Configuration for Multi-Layer PCB .............................................................. 14
JEDEC Standard FR4 Multi-Layer Board – Cross-Sectional View ...................................................... 14
Conducting Heat Away from the Die using an Exposed Pad Package ............................................... 15
Application Using a Single-Layer PCB ................................................................................................ 15
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
4 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
List of Tables
Table 1.1
Absolute Maximum Ratings ................................................................................................................... 6
Table 1.2
Thermal Characteristics for 8-Pin DFN (2mm x 2mm) Package ........................................................... 6
Table 1.3
Recommended Operating Conditions .................................................................................................... 6
Table 1.4
Electrical Characteristics ........................................................................................................................ 7
Table 5.1: Pin Description, 8-Pin DFN (2x2) ............................................................................................................ 12
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
5 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
1
ZSPM4121 Characteristics
Stresses beyond those listed under “Absolute Maximum Ratings” (section 1.1) may cause permanent damage to
the device. These are stress ratings only. Functional operation of the device at these or any other conditions
beyond those recommended under “Recommended Operating Conditions” (section 1.3) is not implied. Exposure
to absolute–maximum conditions for extended periods may affect device reliability.
1.1.
Absolute Maximum Ratings
Over operating free–air temperature range unless otherwise noted. All voltage values are with respect to network
ground terminal.
Table 1.1
Absolute Maximum Ratings
Parameter
Symbol
Value
Unit
Maximum voltage applied to the VCC, VOUT,and NPG pins
-0.3 to 6.0
V
Electrostatic Discharge – Human Body Model, according to
the respective JESD22 JEDEC standard
2
kV
Operating Junction Temperature Range
TJ
-20 to 85
C
Storage Temperature Range
Tstg
-65 to 150
C
260
C
Lead Temperature (soldering, 10 seconds)
1.2.
Thermal Characteristics
Table 1.2
Thermal Characteristics for 8-Pin DFN (2mm x 2mm) Package
JA (C/W)
1)
JC (C/W)
73.1
2)
10.7
1)
This rating assumes a FR4 board only.
2)
This rating assumes a 1oz. copper JEDEC standard board with thermal vias. See section 6.1 for more information.
1.3.
Recommended Operating Conditions
Table 1.3
Recommended Operating Conditions
Parameter
Unregulated Supply Input at VCC pin
Operating Ambient Temperature
Operating Junction Temperature
1)
1)
Symbol
Min
VCC
Typ
Max
Unit
1.2
5.5
V
TA
-20
55
°C
TJ
-20
85
°C
Operating ambient temperature is only intended as a guideline. The operating junction temperature requirements must not be
exceeded.
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
6 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
1.4.
Electrical Characteristics
Electrical characteristics for VCC = 1.2V to 5.5 (unless otherwise noted). Minimum and maximum characteristics
are tested at TJ = 25°C.
Table 1.4
Electrical Characteristics
Parameter
Symbol
Condition
Min
Typ
Max
Unit
5.5
V
150
nA
Input Supply
Input Supply Voltage at
VCC pin
VCC
1.2
Quiescent Current:
On Mode
Iq-ON
VCC = 5V, no load
70
Quiescent Current:
Off Mode
Iq-OFF
VCC < VTHRESH, no load
100
pA
Load Switch
Over-Current Shutdown
IOC
VCC = 5.0V
3
A
Over-Current Retry Period
tOC
VCC = 5.0V
1.7
ms
Output Switch Leakage
Current
ILEAK-SW
VCC < VTHRESH; VOUT grounded
100
pA
Switch ON-Resistance
Rds-on
VCC = 5.0V
175
m
VCC = 3.3V
200
m
VCC = 1.8V
350
m
Transition Times
Transition Delay:
On Mode to Off Mode
td1
VOFF = 2.0V, VCC = 3.0V  1.5V
650
s
Transition Delay:
Off Mode to On Mode
td2
VOFF = 2.0V, VCC = 1.5V  3.0V
1.7
ms
Output Turn-on Rise Time
tON
VCC = 2.5V, RLOAD = 50
200
µs
Output Leakage
ILEAK-NPG
VCC = 5.0V, VNPG = 5.5V
100
nA
Low-Level Output Voltage
VOL-NPG
INPG = 5 mA
0.4
V
1.05 
VTHRESH
V
NPG Output
Off Thresholds
Off Threshold
VOFF
VTHRESH = customer-selected
threshold voltage in the range of
1.2V to 4.2V with 100mV steps
between options programmed at
manufacturing
Off Mode to On Mode
Hysteresis
VHys
Rising Transition:
Off Mode to On Mode
Data Sheet
April 30, 2012
0.95 
VTHRESH
VTHRESH
500
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
mV
7 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
2
Typical Performance Characteristics
T = 25°C (unless otherwise noted)
Figure 2.1
On Mode / Off Mode Characteristics
Figure 2.3 On Mode / Off Mode Quiescent Current Iq
Data Sheet
April 30, 2012
Figure 2.2
On Mode Switching Behavior
Figure 2.4
Off Mode VTHRESH Temperature
Performance
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
8 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
Figure 2.5 On Mode / Off Mode Transition Delay
3
Figure 2.6
Over-Current Retry Performance
Description of Circuit
The ZSPM4121 battery management load switch consists of an internally generated threshold voltage,
comparator with hysteresis, slew rate control for the load switch, a P-channel load switch, and an open-drain
indicator pin. When the input battery voltage is above the factory-configured threshold, the load switch is on (the
On Mode). When the input battery voltage falls to the threshold voltage or below, the load switch is off (the Off
Mode), and the quiescent current draw on the battery is in the order of 100pA (typical). The ZSPM4121 threshold
voltage is programmed at manufacturing to an option in the range of 1.2V to 4.2V with 100mV steps between
options. The 500mV hysteresis between the Off Mode and the On Mode prevents intermittent operation. The
ZSPM4121 also provides over-current protection.
Figure 3.1
ZSPM4121 Block Diagram
ZSPM4121
VCC
VOUT
Regulated
VTHRESH
NPG
GND
Note: At manufacturing, VTHRESH is programmed to a
customer-selected threshold voltage in the range of
1.2V to 4.2V with 100mV steps between options.
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
9 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
4
Application Circuits
4.1.
Typical Application Circuits
Note that when the ZSPM4121 is in Off Mode, the battery will continue to charge through the body diode between
VOUT and VCC for the application shown in Figure 4.1.
Figure 4.1
Application Circuit for Disconnecting the Battery
Charger
Load
ZSPM4121
VOUT
VCC
NPG
GND
Figure 4.2
Application Circuit for Disconnecting the Load
ZSPM4121
Charger
VOUT
Load
VCC
NPG
GND
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
10 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
5
Pin Configuration and Package
5.1.
Package Dimensions and Marking Diagram
Figure 5.1
ZSPM4121 Package Drawing
MARKING CODES:
Z:
P:
V:
ZMDI
Product Code
Voltage levels: 1 = 1.2V, 2 = 1.3V, 3 = 1.4V, 4 = 1.5V, 5 = 1.6V, 6 = 1.7V, 7 = 1.8V. 8 = 1.9V, 9 = 2.0V,
A = 2.1 V, B = 2,2 V, C = 2.3 V, D = 2.4 V, E - V = 2.5V to 4.2V
YM: Date Code (Year, Month)
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
11 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
5.2.
Pin Description for 8-Pin DFN (2x2 mm)
Figure 5.2
ZSPM4121 Pin Assignments (top view)
1
GND
NPG
8
2
VOUT
VCC
7
3
NC
VCC
6
4
NC
NC
5
Table 5.1: Pin Description, 8-Pin DFN (2x2)
Pin #
Name
Function
1
GND
Ground
GND
2
VOUT
Output
Output to System Load
3
NC
No Connection (connect to GND or float)
4
NC
No Connection (connect to GND or float)
5
NC
No Connection (connect to GND or float)
6
VCC
Supply
Supply Input (connect to pin 7 and VCC supply rail)
7
VCC
Supply
Supply Input (connect to pin 6 and VCC supply rail)
8
NPG
Output
Open-Drain N-Channel Output (low indicates “Power Good”)
Data Sheet
April 30, 2012
Description
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
12 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
6
Layout and Soldering Requirements
To maximize the efficiency of this package for applications on a single layer or multi-layer printed circuit board
(PCB), certain guidelines must be followed when laying out this part on the PCB.
6.1.
Recommended Landing Pattern for PCBs
Figure 6.1
Recommended Landing Pattern for 8-Pin DFN
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
13 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
6.2.
Multi-Layer PCB Layout
The following are guidelines for mounting the exposed pad ZSPM4121 on a multi-Layer PCB with ground a plane.
In a multi-layer board application, the thermal vias are the primary method of heat transfer from the package
thermal pad to the internal ground plane. The efficiency of this method depends on several factors, including die
area, number of thermal vias, and thickness of copper, etc.
Figure 6.2
Package and PCB Land Configuration for Multi-Layer PCB
Solder Pad (Land Pattern)
Package Thermal Pad
Thermal Vias
Package Outline
Figure 6.3
JEDEC Standard FR4 Multi-Layer Board – Cross-Sectional View
(square)
Package Solder
Pad
1.5038 - 1.5748 mm
Component Trace
(2oz Cu)
2 Plane
4 Plane
1.5748mm
Component Traces
Thermal Via
Thermal Isolation
Power plane only
1.0142 - 1.0502 mm
Ground Plane
(1oz Cu)
0.5246 - 0.5606 mm
Power Plane
(1oz Cu)
0.0 - 0.071 mm Board
Base & Bottom Pad
Package Solder
Pad (bottom trace)
Figure 6.4 is a representation of how the heat can be conducted away from the die using an exposed pad
package. Each application will have different requirements and limitations, and therefore the user should use
sufficient copper to dissipate the power in the system. The output current rating for the linear regulators might
need to be de-rated for ambient temperatures above 85°C. The de-rated value will depend on calculated worst
case power dissipation and the thermal management implementation in the application.
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
14 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
Figure 6.4
Conducting Heat Away from the Die using an Exposed Pad Package
Mold compound
Die
Epoxy Die attach
Exposed pad
Solder
5% - 10% Cu coverage
Single Layer, 2oz Cu
Ground Layer, 1oz Cu
Signal Layer, 1oz Cu
Thermal Vias with Cu plating
90% Cu coverage
20% Cu coverage
Bottom Layer, 2oz Cu
Note: NOT to scale.
6.3.
Single-Layer PCB Layout
Layout recommendations for a single-layer PCB: Utilize as much copper area for power management as possible.
In a single-layer board application, the thermal pad is attached to a heat spreader (copper areas) by using a low
thermal impedance attachment method (solder paste or thermal conductive epoxy).
In both of the methods mentioned above, it is advisable to use as much copper trace as possible to dissipate the
heat.
Figure 6.5
Application Using a Single-Layer PCB
Use as much copper area
as possible for heat spread
Package Thermal Pad
Package Outline
Important: If the attachment method is NOT implemented correctly, the functionality of the product is NOT
guaranteed. Power dissipation capability will be adversely affected if the device is incorrectly mounted onto the
circuit board.
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
15 of 17
ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
7
Ordering Information
Ordering Code*
Description
Package
ZSPM4121AI1W17
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 1.7V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W21
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.1V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W23
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.3V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W24
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.4V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W25
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.5V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W26
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.6V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W28
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 2.8V
8-pin DFN / 7” Reel (2500)
ZSPM4121AI1W30
ZSPM4121 Under-Voltage Load Switch—VTHRESH factory set to 3.0V
8-pin DFN / 7” Reel (2500)
ZSPM4121KIT
ZSPM4121 Evaluation Kit
* Custom values are also available in the range of 1.2V - 4.2V (typical) in 100mV increments.
8
Related Documents
Document
File Name
ZSPM4121 Feature Sheet
ZSPM4121_Feature_Sheet_revX_xy.pdf
ZSPM4121 Evaluation Kit Description
ZSPM4121_Eval_Kit_Description_revX_xy.pdf
ZSPM4121 Application Note—Low Power
Battery Control and Voltage Regulator
Solutions for Remote Sensor Networks
ZSPM4121_App_Note_LP-Batt-Contr-VReg-Remote-Sensor-Net_X_xy.pdf
Note: X_xy refers to the current revision of the document.
Visit ZMDI’s website www.zmdi.com or contact your nearest sales office for the latest version of these documents.
9
Glossary
Term
Description
PG
Power Good (NPG = Power Good, active low)
RFID
Radio Frequency Identification
SPM
Smart Power Management
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
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ZSPM4121
Under-Voltage Load Switch for Smart Battery Management
10 Document Revision History
Revision
Date
Description
1.00
April 30, 2012
First release
Sales and Further Information
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DISCLAIMER: This information applies to a product under development. Its characteristics and specifications are subject to change without notice. Zentrum Mikroelektronik Dresden AG
(ZMD AG) assumes no obligation regarding future manufacture unless otherwise agreed to in writing. The information furnished hereby is believed to be true and accurate. However, under
no circumstances shall ZMD AG be liable to any customer, licensee, or any other third party for any special, indirect, incidental, or consequential damages of any kind or nature whatsoever
arising out of or in any way related to the furnishing, performance, or use of this technical data. ZMD AG hereby expressly disclaims any liability of ZMD AG to any customer, licensee or
any other third party, and any such customer, licensee and any other third party hereby waives any liability of ZMD AG for any damages in connection with or arising out of the furnishing,
performance or use of this technical data, whether based on contract, warranty, tort (including negligence), strict liability, or otherwise.
Data Sheet
April 30, 2012
© 2012 Zentrum Mikroelektronik Dresden AG — Rev. 1.00
All rights reserved. The material contained herein may not be reproduced, adapted, merged, translated, stored, or used without the
prior written consent of the copyright owner. The information furnished in this publication is subject to changes without notice.
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