S-1002CA36I-M5T1U - Ablic - Datasheet.Live

S-1002 Series

www.ablicinc.com

VOLTAGE DETECTOR WITH SENSE PIN

The S-1002 Series is a high-accuracy voltage detector developed using CMOS technology. The detection voltage is fixed

internally with an accuracy of 1.0% (VDET(S)  2.2 V). It operates with current consumption of 500 nA typ.

Apart from the power supply pin, the detection voltage input pin (SENSE pin) is also prepared, so the output is stable even

if the SENSE pin falls to 0 V.

Two output forms Nch open-drain output and CMOS output are available.

 Features

 Detection voltage: 1.0 V to 5.0 V (0.1 V step)

 Detection voltage accuracy: 1.0% (2.2 V  VDET(S)  5.0 V)

22 mV (1.0 V  VDET(S)  2.2 V)

 Current consumption: 500 nA typ.

 Operation voltage range: 0.95 V to 10.0 V

 Hysteresis width: 5%  2%

 Output form: Nch open-drain output (Active "L")

CMOS output (Active "L")

 Operation temperature range: Ta = 40°C to 85°C

 Lead-free (Sn 100%), halogen-free

 Applications

 Power supply monitor for microcomputer and reset for CPU

 Constant voltage power supply monitor for TV, Blu-ray recorder and home appliance

 Power supply monitor for portable devices such as notebook PC, digital still camera and mobile phone

 Packages

 SOT-23-5

 SC-82AB

www.ablic.com

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Block Diagrams

1. S-1002 Series NA / NB type (Nch open-drain output)

VSS

REF





OUT

VDD

SENSE

Function Status

Output logic Active "L"

*1. Parasitic diode

Figure 1

2. S-1002 Series CA / CB type (CMOS output)

VSS

REF





OUT

VDD

SENSE

Function Status

Output logic Active "L"

*1. Parasitic diode

Figure 2

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

 Product Name Structure

Users can select the output form, detection voltage value, and package type for the S-1002 Series.

Refer to "1. Product name" regarding the contents of product name, "2. Function list of product types" regarding

the product types, "3. Packages" regarding the package drawings and "4. Product name list" regarding details of

product name.

1. Product name

S-1002 x x xx I - xxxx U

Package abbreviation and IC packing specifications*1

M5T1: SOT-23-5, Tape

N4T1: SC-82AB, Tape

Detection voltage value

10 to 50

(e.g., when the detection voltage is 1.0 V, it is expressed as 10.)

Environmental code

U: Lead-free (Sn 100%), halogen-free

Operation temperature

I: Ta = 40C to 85C

Output form*3

N: Nch open-drain output (Active "L")*4

C: CMOS output (Active "L")*4

Pin configuration*2

A, B

*1. Refer to the tape drawing.

*2. Refer to " Pin Configurations".

*3. Refer to "2. Function list of product types".

*4. If you request the product with output logic active "H", contact our sales office.

2. Function list of product types

Table 1

Product Type Output Form Output Logic Pin Configuration Package

NA Nch open-drain output Active "L" A SOT-23-5

NB Active "L" B SOT-23-5, SC-82AB

CA CMOS output Active "L" A SOT-23-5

CB Active "L" B SOT-23-5, SC-82AB

3. Packages

Table 2 Package Drawing Codes

Package Name Dimension Tape Reel

SOT-23-5 MP005-A-P-SD MP005-A-C-SD MP005-A-R-SD

SC-82AB NP004-A-P-SD

NP004-A-C-SD

NP004-A-C-S1 NP004-A-R-SD

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

4. Product name list

4. 1 S-1002 Series NA type

Output form: Nch open-drain output (Active "L")

Table 3

Detection Voltage SOT-23-5

1.0 V  22 mV S-1002NA10I-M5T1U

1.1 V  22 mV S-1002NA11I-M5T1U

1.2 V  22 mV S-1002NA12I-M5T1U

1.3 V  22 mV S-1002NA13I-M5T1U

1.4 V  22 mV S-1002NA14I-M5T1U

1.5 V  22 mV S-1002NA15I-M5T1U

1.6 V  22 mV S-1002NA16I-M5T1U

1.7 V  22 mV S-1002NA17I-M5T1U

1.8 V  22 mV S-1002NA18I-M5T1U

1.9 V  22 mV S-1002NA19I-M5T1U

2.0 V  22 mV S-1002NA20I-M5T1U

2.1 V  22 mV S-1002NA21I-M5T1U

2.2 V  1.0% S-1002NA22I-M5T1U

2.3 V  1.0% S-1002NA23I-M5T1U

2.4 V  1.0% S-1002NA24I-M5T1U

2.5 V  1.0% S-1002NA25I-M5T1U

2.6 V  1.0% S-1002NA26I-M5T1U

2.7 V  1.0% S-1002NA27I-M5T1U

2.8 V  1.0% S-1002NA28I-M5T1U

2.9 V  1.0% S-1002NA29I-M5T1U

3.0 V  1.0% S-1002NA30I-M5T1U

3.1 V  1.0% S-1002NA31I-M5T1U

3.2 V  1.0% S-1002NA32I-M5T1U

3.3 V  1.0% S-1002NA33I-M5T1U

3.4 V  1.0% S-1002NA34I-M5T1U

3.5 V  1.0% S-1002NA35I-M5T1U

3.6 V  1.0% S-1002NA36I-M5T1U

3.7 V  1.0% S-1002NA37I-M5T1U

3.8 V  1.0% S-1002NA38I-M5T1U

3.9 V  1.0% S-1002NA39I-M5T1U

4.0 V  1.0% S-1002NA40I-M5T1U

4.1 V  1.0% S-1002NA41I-M5T1U

4.2 V  1.0% S-1002NA42I-M5T1U

4.3 V  1.0% S-1002NA43I-M5T1U

4.4 V  1.0% S-1002NA44I-M5T1U

4.5 V  1.0% S-1002NA45I-M5T1U

4.6 V  1.0% S-1002NA46I-M5T1U

4.7 V  1.0% S-1002NA47I-M5T1U

4.8 V  1.0% S-1002NA48I-M5T1U

4.9 V  1.0% S-1002NA49I-M5T1U

5.0 V  1.0% S-1002NA50I-M5T1U

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

4. 2 S-1002 Series NB type

Output form: Nch open-drain output (Active "L")

Table 4

Detection Voltage SOT-23-5 SC-82AB

1.0 V  22 mV S-1002NB10I-M5T1U S-1002NB10I-N4T1U

1.1 V  22 mV S-1002NB11I-M5T1U S-1002NB11I-N4T1U

1.2 V  22 mV S-1002NB12I-M5T1U S-1002NB12I-N4T1U

1.3 V  22 mV S-1002NB13I-M5T1U S-1002NB13I-N4T1U

1.4 V  22 mV S-1002NB14I-M5T1U S-1002NB14I-N4T1U

1.5 V  22 mV S-1002NB15I-M5T1U S-1002NB15I-N4T1U

1.6 V  22 mV S-1002NB16I-M5T1U S-1002NB16I-N4T1U

1.7 V  22 mV S-1002NB17I-M5T1U S-1002NB17I-N4T1U

1.8 V  22 mV S-1002NB18I-M5T1U S-1002NB18I-N4T1U

1.9 V  22 mV S-1002NB19I-M5T1U S-1002NB19I-N4T1U

2.0 V  22 mV S-1002NB20I-M5T1U S-1002NB20I-N4T1U

2.1 V  22 mV S-1002NB21I-M5T1U S-1002NB21I-N4T1U

2.2 V  1.0% S-1002NB22I-M5T1U S-1002NB22I-N4T1U

2.3 V  1.0% S-1002NB23I-M5T1U S-1002NB23I-N4T1U

2.4 V  1.0% S-1002NB24I-M5T1U S-1002NB24I-N4T1U

2.5 V  1.0% S-1002NB25I-M5T1U S-1002NB25I-N4T1U

2.6 V  1.0% S-1002NB26I-M5T1U S-1002NB26I-N4T1U

2.7 V  1.0% S-1002NB27I-M5T1U S-1002NB27I-N4T1U

2.8 V  1.0% S-1002NB28I-M5T1U S-1002NB28I-N4T1U

2.9 V  1.0% S-1002NB29I-M5T1U S-1002NB29I-N4T1U

3.0 V  1.0% S-1002NB30I-M5T1U S-1002NB30I-N4T1U

3.1 V  1.0% S-1002NB31I-M5T1U S-1002NB31I-N4T1U

3.2 V  1.0% S-1002NB32I-M5T1U S-1002NB32I-N4T1U

3.3 V  1.0% S-1002NB33I-M5T1U S-1002NB33I-N4T1U

3.4 V  1.0% S-1002NB34I-M5T1U S-1002NB34I-N4T1U

3.5 V  1.0% S-1002NB35I-M5T1U S-1002NB35I-N4T1U

3.6 V  1.0% S-1002NB36I-M5T1U S-1002NB36I-N4T1U

3.7 V  1.0% S-1002NB37I-M5T1U S-1002NB37I-N4T1U

3.8 V  1.0% S-1002NB38I-M5T1U S-1002NB38I-N4T1U

3.9 V  1.0% S-1002NB39I-M5T1U S-1002NB39I-N4T1U

4.0 V  1.0% S-1002NB40I-M5T1U S-1002NB40I-N4T1U

4.1 V  1.0% S-1002NB41I-M5T1U S-1002NB41I-N4T1U

4.2 V  1.0% S-1002NB42I-M5T1U S-1002NB42I-N4T1U

4.3 V  1.0% S-1002NB43I-M5T1U S-1002NB43I-N4T1U

4.4 V  1.0% S-1002NB44I-M5T1U S-1002NB44I-N4T1U

4.5 V  1.0% S-1002NB45I-M5T1U S-1002NB45I-N4T1U

4.6 V  1.0% S-1002NB46I-M5T1U S-1002NB46I-N4T1U

4.7 V  1.0% S-1002NB47I-M5T1U S-1002NB47I-N4T1U

4.8 V  1.0% S-1002NB48I-M5T1U S-1002NB48I-N4T1U

4.9 V  1.0% S-1002NB49I-M5T1U S-1002NB49I-N4T1U

5.0 V  1.0% S-1002NB50I-M5T1U S-1002NB50I-N4T1U

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

4. 3 S-1002 Series CA type

Output form: CMOS output (Active "L")

Table 5

Detection Voltage SOT-23-5

1.0 V  22 mV S-1002CA10I-M5T1U

1.1 V  22 mV S-1002CA11I-M5T1U

1.2 V  22 mV S-1002CA12I-M5T1U

1.3 V  22 mV S-1002CA13I-M5T1U

1.4 V  22 mV S-1002CA14I-M5T1U

1.5 V  22 mV S-1002CA15I-M5T1U

1.6 V  22 mV S-1002CA16I-M5T1U

1.7 V  22 mV S-1002CA17I-M5T1U

1.8 V  22 mV S-1002CA18I-M5T1U

1.9 V  22 mV S-1002CA19I-M5T1U

2.0 V  22 mV S-1002CA20I-M5T1U

2.1 V  22 mV S-1002CA21I-M5T1U

2.2 V  1.0% S-1002CA22I-M5T1U

2.3 V  1.0% S-1002CA23I-M5T1U

2.4 V  1.0% S-1002CA24I-M5T1U

2.5 V  1.0% S-1002CA25I-M5T1U

2.6 V  1.0% S-1002CA26I-M5T1U

2.7 V  1.0% S-1002CA27I-M5T1U

2.8 V  1.0% S-1002CA28I-M5T1U

2.9 V  1.0% S-1002CA29I-M5T1U

3.0 V  1.0% S-1002CA30I-M5T1U

3.1 V  1.0% S-1002CA31I-M5T1U

3.2 V  1.0% S-1002CA32I-M5T1U

3.3 V  1.0% S-1002CA33I-M5T1U

3.4 V  1.0% S-1002CA34I-M5T1U

3.5 V  1.0% S-1002CA35I-M5T1U

3.6 V  1.0% S-1002CA36I-M5T1U

3.7 V  1.0% S-1002CA37I-M5T1U

3.8 V  1.0% S-1002CA38I-M5T1U

3.9 V  1.0% S-1002CA39I-M5T1U

4.0 V  1.0% S-1002CA40I-M5T1U

4.1 V  1.0% S-1002CA41I-M5T1U

4.2 V  1.0% S-1002CA42I-M5T1U

4.3 V  1.0% S-1002CA43I-M5T1U

4.4 V  1.0% S-1002CA44I-M5T1U

4.5 V  1.0% S-1002CA45I-M5T1U

4.6 V  1.0% S-1002CA46I-M5T1U

4.7 V  1.0% S-1002CA47I-M5T1U

4.8 V  1.0% S-1002CA48I-M5T1U

4.9 V  1.0% S-1002CA49I-M5T1U

5.0 V  1.0% S-1002CA50I-M5T1U

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

4. 4 S-1002 Series CB type

Output form: CMOS output (Active "L")

Table 6

Detection Voltage SOT-23-5 SC-82AB

1.0 V  22 mV S-1002CB10I-M5T1U S-1002CB10I-N4T1U

1.1 V  22 mV S-1002CB11I-M5T1U S-1002CB11I-N4T1U

1.2 V  22 mV S-1002CB12I-M5T1U S-1002CB12I-N4T1U

1.3 V  22 mV S-1002CB13I-M5T1U S-1002CB13I-N4T1U

1.4 V  22 mV S-1002CB14I-M5T1U S-1002CB14I-N4T1U

1.5 V  22 mV S-1002CB15I-M5T1U S-1002CB15I-N4T1U

1.6 V  22 mV S-1002CB16I-M5T1U S-1002CB16I-N4T1U

1.7 V  22 mV S-1002CB17I-M5T1U S-1002CB17I-N4T1U

1.8 V  22 mV S-1002CB18I-M5T1U S-1002CB18I-N4T1U

1.9 V  22 mV S-1002CB19I-M5T1U S-1002CB19I-N4T1U

2.0 V  22 mV S-1002CB20I-M5T1U S-1002CB20I-N4T1U

2.1 V  22 mV S-1002CB21I-M5T1U S-1002CB21I-N4T1U

2.2 V  1.0% S-1002CB22I-M5T1U S-1002CB22I-N4T1U

2.3 V  1.0% S-1002CB23I-M5T1U S-1002CB23I-N4T1U

2.4 V  1.0% S-1002CB24I-M5T1U S-1002CB24I-N4T1U

2.5 V  1.0% S-1002CB25I-M5T1U S-1002CB25I-N4T1U

2.6 V  1.0% S-1002CB26I-M5T1U S-1002CB26I-N4T1U

2.7 V  1.0% S-1002CB27I-M5T1U S-1002CB27I-N4T1U

2.8 V  1.0% S-1002CB28I-M5T1U S-1002CB28I-N4T1U

2.9 V  1.0% S-1002CB29I-M5T1U S-1002CB29I-N4T1U

3.0 V  1.0% S-1002CB30I-M5T1U S-1002CB30I-N4T1U

3.1 V  1.0% S-1002CB31I-M5T1U S-1002CB31I-N4T1U

3.2 V  1.0% S-1002CB32I-M5T1U S-1002CB32I-N4T1U

3.3 V  1.0% S-1002CB33I-M5T1U S-1002CB33I-N4T1U

3.4 V  1.0% S-1002CB34I-M5T1U S-1002CB34I-N4T1U

3.5 V  1.0% S-1002CB35I-M5T1U S-1002CB35I-N4T1U

3.6 V  1.0% S-1002CB36I-M5T1U S-1002CB36I-N4T1U

3.7 V  1.0% S-1002CB37I-M5T1U S-1002CB37I-N4T1U

3.8 V  1.0% S-1002CB38I-M5T1U S-1002CB38I-N4T1U

3.9 V  1.0% S-1002CB39I-M5T1U S-1002CB39I-N4T1U

4.0 V  1.0% S-1002CB40I-M5T1U S-1002CB40I-N4T1U

4.1 V  1.0% S-1002CB41I-M5T1U S-1002CB41I-N4T1U

4.2 V  1.0% S-1002CB42I-M5T1U S-1002CB42I-N4T1U

4.3 V  1.0% S-1002CB43I-M5T1U S-1002CB43I-N4T1U

4.4 V  1.0% S-1002CB44I-M5T1U S-1002CB44I-N4T1U

4.5 V  1.0% S-1002CB45I-M5T1U S-1002CB45I-N4T1U

4.6 V  1.0% S-1002CB46I-M5T1U S-1002CB46I-N4T1U

4.7 V  1.0% S-1002CB47I-M5T1U S-1002CB47I-N4T1U

4.8 V  1.0% S-1002CB48I-M5T1U S-1002CB48I-N4T1U

4.9 V  1.0% S-1002CB49I-M5T1U S-1002CB49I-N4T1U

5.0 V  1.0% S-1002CB50I-M5T1U S-1002CB50I-N4T1U

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Pin Configurations

1. S-1002 Series NA / CA type

1. 1 SOT-23-5

132

Top view

Figure 3

Table 7 Pin Configuration A

Pin No. Symbol Description

1 OUT Voltage detection output pin

2 VDD Power supply pin

3 VSS GND pin

NC*1 No connection

5 SENSE Detection voltage input pin

*1. The NC pin is electrically open.

The NC pin can be connected to the VDD pin or the VSS pin.

2. S-1002 Series NB / CB type

2. 1 SOT-23-5

132

Top view

Figure 4

Table 8 Pin Configuration B

Pin No. Symbol Description

1 OUT Voltage detection output pin

2 VSS GND pin

3 VDD Power supply pin

4 SENSE Detection voltage input pin

NC*1 No connection

*1. The NC pin is electrically open.

The NC pin can be connected to the VDD pin or the VSS pin.

2. 2 SC-82AB

Top view

Figure 5

Table 9 Pin Configuration B

Pin No. Symbol Description

1 SENSE Detection voltage input pin

2 VDD Power supply pin

3 OUT Voltage detection output pin

4 VSS GND pin

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

 Absolute Maximum Ratings

Table 10

(Ta = 25°C unless otherwise specified)

Item Symbol Absolute Maximum Rating Unit

Power supply voltage VDDVSS 12.0 V

SENSE pin input voltage VSENSE V

SS  0.3 to 12.0 V

Output voltage Nch open-drain output product VOUT VSS  0.3 to 12.0 V

CMOS output product VSS  0.3 to VDD  0.3 V

Output current IOUT 50 mA

Power dissipation SOT-23-5 PD 600*1 mW

SC-82AB 350*1 mW

Operation ambient temperature To

40 to 85 °C

Storage temperature Tst

40 to 125 °C

*1. When mounted on board

[Mounted board]

(1) Board size: 114.3 mm  76.2 mm  t1.6 mm

(2) Name: JEDEC STANDARD51-7

Caution The absolute maximum ratings are rated values exceeding which the product could suffer

physical damage. These values must therefore not be exceeded under any conditions.

0 50 100 150

Power Dissipation (PD) [mW]

Ambient Temperature (Ta) [C]

200

100

300

500

700

SOT-23-5

SC-82AB

400

600

Figure 6 Power Dissipation of Package (When Mounted on Board)

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Electrical Characteristics

1. Nch open-drain output product

Table 11

(Ta = 25°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit Test

Circuit

Detection voltage*1 VDET 0.95 V  VDD  10.0 V

1.0 V  VDET(S)  2.2 V VDET(S)

 0.022 VDET(S) VDET(S)

 0.022 V 1

2.2 V  VDET(S)  5.0 V VDET(S)

 0.99 VDET(S) VDET(S)

 1.01 V 1

Hysteresis width VHYS  VDET

 0.03

VDET

 0.05

VDET

 0.07 V 1

Current

consumption*2 ISS V

DD = 10.0 V, VSENSE = VDET(S)  1.0 V  0.50 0.90 A 2

Operation voltage VDD  0.95  10.0 V 1

Output current IOUT

Output transistor

Nch

VDS*3 = 0.5 V

VSENSE = 0.0 V

VDD = 0.95 V 0.59 1.00  mA 3

VDD = 1.2 V 0.73 1.33  mA 3

VDD = 2.4 V 1.47 2.39  mA 3

VDD = 4.8 V 1.86 2.50  mA 3

Leakage current ILEAK

Output transistor

Nch

VDD = 10.0 V, VDS*3 = 10.0 V, VSENSE = 10.0 V

  0.08 A 3

Detection voltage

temperature

coefficient*4

VDET

Ta VDET Ta = 40°C to 85°C  100350ppm/C1

Detection

delay time*5 tDET V

DD = 5.0 V  40  s 4

Release

delay time*6 tRESET V

DD = 5.0 V VDET

(

)

 2.4 V  40  s 4

2.4 V  VDET

(

)

 80  s 4

SENSE pin

resistance RSENSE 1.0 V  VDET

(

)

 1.2 V 5.0 19.0 42.0 M 2

1.2 V  VDET

(

)

 5.0 V 6.0 30.0 98.0 M 2

*1. VDET: Actual detection voltage value, VDET(S): Set detection voltage value (the center value of the detection voltage

range in Table 3 or Table 4)

*2. The current flowing through the SENSE pin resistance is not included.

*3. V

DS: Drain-to-source voltage of the output transistor

*4. The temperature change of the detection voltage [mV/°C] is calculated by using the following equation.

VDET

Ta []

mV/°C *1 = VDET(S) (typ.)[]

V*2  VDET

Ta  VDET []

ppm/°C *3  1000

*1. Temperature change of the detection voltage

*2. Set detection voltage

*3. Detection voltage temperature coefficient

*5. The time period from when the pulse voltage of 6.0 V  VDET(S)  2.0 V or 0 V is applied to the SENSE pin to when

VOUT reaches VDD / 2, after the output pin is pulled up to 5.0 V by the resistance of 470 k.

*6. The time period from when the pulse voltage of 0 V  VDET(S)  2.0 V or 6.0 V is applied to the SENSE pin to when

VOUT reaches VDD / 2, after the output pin is pulled up to 5.0 V by the resistance of 470 k.

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

2. CMOS output product

Table 12

(Ta = 25°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit Test

Circuit

Detection voltage*1 VDET 0.95 V  VDD  10.0 V

1.0 V  VDET(S)  2.2 V VDET(S)

 0.022 VDET(S) VDET(S)

 0.022 V 1

2.2 V  VDET(S)  5.0 V VDET(S)

 0.99 VDET(S) VDET(S)

 1.01 V 1

Hysteresis width VHYS  VDET

 0.03

VDET

 0.05

VDET

 0.07 V 1

Current

consumption*2 ISS V

DD = 10.0 V, VSENSE = VDET(S)  1.0 V  0.50 0.90 A 2

Operation voltage VDD  0.95  10.0 V 1

Output current IOUT

Output transistor

Nch

VDS*3 = 0.5 V

VSENSE = 0.0 V

VDD = 0.95 V 0.59 1.00  mA 3

VDD = 1.2 V 0.73 1.33  mA 3

VDD = 2.4 V 1.47 2.39  mA 3

VDD = 4.8 V 1.86 2.50  mA 3

Output transistor

Pch VDD = 4.8 V 1.62 2.60  mA 5

VDS*3 = 0.5 V

VSENSE = 10.0 V VDD = 6.0 V 1.78 2.86  mA 5

Detection voltage

temperature

coefficient*4

VDET

Ta VDET Ta = 40°C to 85°C 100350 ppm/C1

Detection

delay time*5 tDET V

DD = 5.0 V  40  s 4

Release

delay time*6 tRESET V

DD = 5.0 V VDET

(

)

 2.4 V  40  s 4

2.4 V  VDET

(

)

 80  s 4

SENSE pin

resistance RSENSE 1.0 V  VDET

(

)

 1.2 V 5.0 19.0 42.0 M 2

1.2 V  VDET

(

)

 5.0 V6.0 30.0 98.0 M 2

*1. VDET: Actual detection voltage value, VDET(S): Set detection voltage value (the center value of the detection voltage

range in Table 5 or Table 6)

*2. The current flowing through the SENSE pin resistance is not included.

*3. V

DS: Drain-to-source voltage of the output transistor

*4. The temperature change of the detection voltage [mV/°C] is calculated by using the following equation.

VDET

Ta []

mV/°C *1 = VDET(S) (typ.)[]

V*2  VDET

Ta  VDET []

ppm/°C *3  1000

*1. Temperature change of the detection voltage

*2. Set detection voltage

*3. Detection voltage temperature coefficient

*5. The time period from when the pulse voltage of 6.0 V  VDET(S)  2.0 V or 0 V is applied to the SENSE pin to when

VOUT reaches VDD / 2.

*6. The time period from when the pulse voltage of 0 V  VDET(S)  2.0 V or 6.0 V is applied to the SENSE pin to when

VOUT reaches VDD / 2.

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Test Circuits

VDD VDD

VSS

OUT

100 k

SENSE





VDD

VSS

OUT

SENSE



Figure 7 Test Circuit 1 Figure 8 Test Circuit 1

(Nch open-drain output product) (CMOS output product)

VDD

OUT

VDD

VSS



SENSE



VDS

VDD





VDD

VSS

OUT

SENSE

Figure 9 Test Circuit 2 Figure 10 Test Circuit 3

VDD VDD

VSS

OUT

470 k

SENSE

P.G.

Oscilloscope

VDD

VSS

OUT

SENSE

P.G.

Oscilloscope

Figure 11 Test Circuit 4 Figure 12 Test Circuit 4

(Nch open-drain output product) (CMOS output product)

VDD

VDS

VDD

VSS

OUT



SENSE



Figure 13 Test Circuit 5

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

 Standard Circuits

1. Nch open-drain output product

VDD

OUT

VSS

100 k

SENSE

Figure 14

2. CMOS output product

VDD

OUT

VSS

SENSE

Figure 15

Caution The above connection diagram and constant will not guarantee successful operation.

Perform thorough evaluation using the actual application to set the constant.

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Explanation of Terms

1. Detection voltage (VDET)

The detection voltage is a voltage at which the output in Figure 18 or Figure 19 turns to "L". The detection voltage

varies slightly among products of the same specification. The variation of detection voltage between the specified

minimum (VDET min.) and the maximum (VDET max.) is called the detection voltage range (Refer to Figure 16).

Example: In the S-1002Cx18, the detection voltage is either one in the range of 1.778 V  VDET  1.822 V.

This means that some S-1002Cx18 have VDET = 1.778 V and some have VDET = 1.822 V.

2. Release voltage (VDET)

The release voltage is a voltage at which the output in Figure 18 or Figure 19 turns to "H". The release voltage

varies slightly among products of the same specification. The variation of release voltage between the specified

minimum (VDET min.) and the maximum (VDET max.) is called the release voltage range (Refer to Figure 17). The

range is calculated from the actual detection voltage (VDET) of a product and is in the range of VDET  1.03 

VDET  VDET  1.07.

Example: For the S-1002Cx18, the release voltage is either one in the range of 1.832 V  VDET  1.949 V.

This means that some S-1002Cx18 have VDET = 1.832 V and some have VDET = 1.949 V.

SENSE

V

DET

min.

V

DET

max.

OUT

DET

Detection voltage

range

SENSE

V

DET

min.

V

DET

max.

OUT

Release voltage

range

RESET

Release voltage

Figure 16 Detection Voltage Figure 17 Release Voltage

VDD VDD

VSS

OUT

100 k

SENSE





VDD

VSS

OUT

SENSE



Figure 18 Test Circuit of Detection Voltage Figure 19 Test Circuit of Detection Voltage

and Release Voltage and Release Voltage

(Nch open-drain output product) (CMOS output product)

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

3. Hysteresis width (VHYS)

The hysteresis width is the voltage difference between the detection voltage and the release voltage (the voltage at

point B  the voltage at point A = VHYS in "Figure 22 Timing Chart of S-1002 Series NA / NB Type" and "Figure

24 Timing Chart of S-1002 Series CA / CB Type"). Setting the hysteresis width between the detection voltage

and the release voltage, prevents malfunction caused by noise on the input voltage.

4. Feed-through current

The feed-through current is a current that flows instantaneously to the VDD pin at the time of detection and release

of a voltage detector. The feed-through current is large in CMOS output product, small in Nch open-drain output

product.

5. Oscillation

In applications where an input resistor is connected (Figure 20), taking a CMOS output (active "L") product for

example, the feed-through current which is generated when the output goes from "L" to "H" (at the time of release)

causes a voltage drop equal to [feed-through current]  [input resistance]. Since the VDD pin and the SENSE pin

are shorted as in Figure 20, the SENSE pin voltage drops at the time of release. Then the SENSE pin voltage

drops below the detection voltage and the output goes from "H" to "L". In this status, the feed-through current stops

and its resultant voltage drop disappears, and the output goes from "L" to "H". The feed-through current is then

generated again, a voltage drop appears, and repeating the process finally induces oscillation.

(CMOS output product)

GND

VDD

VSS

OUT

SENSE

Figure 20 Example for Bad Implementation Due to Detection Voltage Change

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Operation

1. Basic operation

1. 1 S-1002 Series NA / NB type

(1) When the power supply voltage (VDD) is the minimum operation voltage or higher, and the SENSE pin voltage

(VSENSE) is the release voltage (VDET) or higher, the Nch transistor is turned off to output VDD ("H") when the

output is pulled up. Since the Nch transistor (N1) is turned off, the input voltage to the comparator is

(RB  RC )  VSENSE

RA  RB  RC .

(2) Even if VSENSE decreases to VDET or lower, V

DD is output when VSENSE is higher than the detection voltage

(VDET).

When VSENSE decreases to VDET or lower (point A in Figure 22), the Nch transistor is turned on. And then VSS

("L") is output from the OUT pin after the elapse of the detection delay time (tDET).

At this time, N1 is turned on, and the input voltage to the comparator is RB  VSENSE

RA  RB .

(3) Even if VSENSE further decreases to the IC's minimum operation voltage or lower, the output from the OUT pin is

stable when VDD is minimum operation voltage or higher.

(4) Even if VSENSE exceeds VDET, VSS is output when VSENSE is lower than VDET.

(5) When VSENSE increases to VDET or higher (point B in Figure 22), the Nch transistor is turned off. And then VDD

is output from the OUT pin after the elapse of the release delay time (tRESET) when the output is pulled up.

VSS

REF



 OUT

VDD

SENSE



100 k

SENSE

Nch

*1. Parasitic diode

Figure 21 Operation of S-1002 Series NA / NB Type

SENSE

(1) (2) (3) (5)(4)

DET

RESET

Hysteresis width

HYS

)

Minimum operation voltage

Output from OUT pin

Release voltage (V

DET

)

Detection voltage (V

DET

)

Figure 22 Timing Chart of S-1002 Series NA / NB Type

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

1. 2 S-1002 Series CA / CB type

(1) When the power supply voltage (VDD) is the minimum operation voltage or higher, and the SENSE pin voltage

(VSENSE) is the release voltage (VDET) or higher, the Nch transistor is turned off and the Pch transistor is turned

on to output VDD ("H"). Since the Nch transistor (N1) is turned off, the input voltage to the comparator is

(RB  RC )  VSENSE

RA  RB  RC .

(2) Even if VSENSE decreases to VDET or lower, V

DD is output when VSENSE is higher than the detection voltage

(VDET).

When VSENSE decreases to VDET or lower (point A in Figure 24), the Nch transistor is turned on and the Pch

transistor is turned off. And then VSS ("L") is output from the OUT pin after the elapse of the detection delay time

(tDET).

At this time, N1 is turned on, and the input voltage to the comparator is RB  VSENSE

RA  RB .

(3) Even if VSENSE further decreases to the IC's minimum operation voltage or lower, the output from the OUT pin is

stable when VDD is minimum operation voltage or higher.

(4) Even if VSENSE exceeds VDET, VSS is output when VSENSE is lower than VDET.

(5) When VSENSE increases to VDET or higher (point B in Figure 24), the Nch transistor is turned off and the Pch

transistor is turned on. And then VDD is output from the OUT pin after the elapse of the release delay time

(tRESET).

VSS

REF



 OUT

VDD

SENSE



SENSE

Nch

Pch

*1. Parasitic diode

Figure 23 Operation of S-1002 Series CA / CB Type

SENSE

(1) (2) (3) (5)(4)

DET

RESET

Hysteresis width

HYS

)

Minimum operation voltage

Output from OUT pin

Release voltage (V

DET

)

Detection voltage (V

DET

)

Figure 24 Timing Chart of S-1002 Series CA / CB Type

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

2. SENSE pin

2. 1 Error when detection voltage is set externally

By connecting a node that was resistance-divided by the resistor (RA) and the resistor (RB) to the SENSE pin as

seen in Figure 25, the detection voltage can be set externally.

For conventional products without the SENSE pin, RA cannot be too large since the resistance-divided node must

be connected to the VDD pin. This is because a feed-through current will flow through the VDD pin when it goes

from detection to release, and if RA is large, problems such as oscillation or larger error in the hysteresis width may

occur.

In the S-1002 Series, RA and RB are easily made larger since the resistance-divided node can be connected to the

SENSE pin through which no feed-through current flows. However, be careful of error in the current flowing through

the internal resistance (RSENSE) that will occur.

Although RSENSE in the S-1002 Series is large (5 M min.) to make the error small, RA and RB should be selected

such that the error is within the allowable limits.

2. 2 Selection of RA and RB

In Figure 25, the relation between the external setting detection voltage (VDX) and the actual detection voltage

(VDET) is ideally calculated by the equation below.

VDX = VDET  ()

1  RA

RB ··· (1)

However, in reality there is an error in the current flowing through RSENSE.

When considering this error, the relation between VDX and VDET is calculated as follows.

VDX = VDET  ()

1  RA

RB || RSENSE

= VDET 













1  RA

RB  RSENSE

RB  RSENSE

= VDET  ()

1  RA

RB  RA

RSENSE  VDET ··· (2)

By using equations (1) and (2), the error is calculated as VDET  RA

RSENSE .

The error rate is calculated as follows by dividing the error by the right-hand side of equation (1).

RA  RB

RSENSE  (RA  RB)  100 [%] = RA || RB

RSENSE  100 [%] ··· (3)

As seen in equation (3), the smaller the resistance values of RA and RB compared to RSENSE, the smaller the error

rate becomes.

Also, the relation between the external setting hysteresis width (VHX) and the hysteresis width (VHYS) is calculated

by equation below. Error due to RSENSE also occurs to the relation in a similar way to the detection voltage.

VHX = VHYS  ()

1  RA

RB ··· (4)

VSS

OUT

VDD

SENSE



DET

SENSE

Figure 25 Detection Voltage External Setting Circuit

Caution If RA and RB are large, the SENSE pin input impedance becomes higher and may cause a

malfunction due to noise. In this case, connect a capacitor between the SENSE pin and the VSS

pin.

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

2. 3 Power on sequence

Apply power in the order, the VDD pin then the SENSE pin.

As seen in Figure 26, when VSENSE  VDET, the OUT pin output (VOUT) rises and the S-1002 Series becomes the

release status (normal operation).

SENSE

OUT



DET

RESET

Figure 26

Caution If power is applied in the order the SENSE pin then the VDD pin, an erroneous release may occur

even if VSENSE  VDET.

2. 4 Precautions when shorting between the VDD pin and the SENSE pin

2. 4. 1 Input resistor

Do not connect the input resistor (RA) when shorting between the VDD pin and the SENSE pin.

A feed-through current flows through the VDD pin at the time of release. When connecting the circuit shown as

Figure 27, the feed-through current of the VDD pin flowing through RA will cause a drop in VSENSE at the time of

release.

At that time, oscillation may occur if VSENSE  VDET.

VSS

OUT

VDD

SENSE

Figure 27

2. 4. 2 Parasitic resistance and parasitic capacitance

Due to the difference in parasitic resistance and parasitic capacitance of the VDD pin and the SENSE pin,

power may be applied to the SENSE pin first.

Note that an erroneous release may occur if this happens (refer to "2. 3 Power on sequence").

Caution In CMOS output product, make sure that the VDD pin input impedance does not become too

high, regardless of the above. Since a feed-through current is large, a malfunction may occur if

the VDD pin voltage changes greatly at the time of release.

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

2. 5 Malfunction when VDD falls

As seen in Figure 28, note that if the VDD pin voltage (VDD) drops steeply below 1.2 V when VDET  V

SENSE 

VDET, erroneous detection may occur.

When VDD_Low  1.2 V, erroneous detection does not occur.

When VDD_Low  1.2 V, the more the VDD falling amplitude increases or the shorter the falling time becomes, the

easier the erroneous detection.

Perform thorough evaluation in actual application.

SENSE

OUT



DET



DET

DD_High

OUT

falling influenced by V

falling

(erroneous detection)

DD_Low

(Voltage drops below 1.2 V.)

Figure 28

The S-1002Cx50 example in Figure 29 shows an example of erroneous detection boundary conditions.

0.1

DD_High

[V]

[s]

10001 10010

Danger of erroneous

detection

Figure 29

Remark Test conditions

Product name: S-1002Cx50

SENSE: VDET(S)  0.1 V

DD_High: VDD pin voltage before falling

DD_Low: VDD pin voltage after falling (0.95 V)

VDD: VDD_High  VDD_Low

F: Falling time of VDD from VDD_High  VDD  10% to VDD_Low  VDD  10%

DD_High

DD_Low

DD_High

 V

 10%

DD_Low

 V

 10%

Figure 30

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

3. Other characteristics

3. 1 Temperature characteristics of detection voltage

The shaded area in Figure 31 shows the temperature characteristics of detection voltage in the operation

temperature range.

40 25

0.945 mV/°C

V

DET

[V]

85 Ta [°C]

0.945 mV/°C

V

DET25*1

*1. VDET25 is a detection voltage value at Ta = 25°C.

Figure 31 Temperature Characteristics of Detection Voltage (Example for VDET = 2.7 V)

3. 2 Temperature characteristics of release voltage

The temperature change VDET

Ta of the release voltage is calculated by using the temperature change

VDET

Ta of the detection voltage as follows:

VDET

Ta = VDET

VDET  VDET

Ta

The temperature change of the release voltage and the detection voltage has the same sign consequently.

3. 3 Temperature characteristics of hysteresis voltage

The temperature change of the hysteresis voltage is expressed as VDET

Ta  VDET

Ta and is calculated as

follows:

VDET

Ta  VDET

Ta = VHYS

VDET  VDET

Ta

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Precautions

 Do not apply an electrostatic discharge to this IC that exceeds the performance ratings of the built-in electrostatic

protection circuit.

 In CMOS output product of the S-1002 Series, the feed-through current flows at the time of detection and release. If

the VDD pin input impedance is high, malfunction may occur due to the voltage drop by the feed-through current

when releasing.

 In CMOS output product, oscillation may occur if a pull-down resistor is connected and falling speed of the SENSE

pin voltage (VSENSE) is slow near the detection voltage when the VDD pin and the SENSE pin are shorted.

 When designing for mass production using an application circuit described herein, the product deviation and

temperature characteristics of the external parts should be taken into consideration. ABLIC Inc. shall not bear any

responsibility for patent infringements related to products using the circuits described herein.

 ABLIC Inc. claims no responsibility for any disputes arising out of or in connection with any infringement by

products including this IC of patents owned by a third party.

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

 Characteristics (Typical Data)

1. Detection voltage (VDET), Release voltage (VDET) vs. Temperature (Ta)

S-1002Cx10 VDD = 5.0 V

1.2

V

DET

, V

DET

[V]



40 857550250



Ta [ C]

1.1

1.0

0.9

0.8

V

DET

V

DET

S-1002Cx24 VDD = 5.0 V

2.6

V

DET

, V

DET

[V]



40 857550250



Ta [ C]

2.5

2.4

2.3

2.2

V

DET

V

DET

S-1002Cx50 VDD = 5.0 V

5.4

V

DET

, V

DET

[V]



40 857550250



Ta [ C]

5.2

5.0

4.8

4.6

V

DET

V

DET

2. Hysteresis width (VHYS) vs. Temperature (Ta)

S-1002Cx10 VDD = 5.0 V

HYS

[%]



40 857550250



Ta [ C]

7.0

6.0

5.0

4.0

3.0

S-1002Cx24 VDD = 5.0 V

HYS

[%]



40 857550250



Ta [ C]

7.0

6.0

5.0

4.0

3.0

S-1002Cx50 VDD = 5.0 V

HYS

[%]



40 857550250



Ta [ C]

7.0

6.0

5.0

4.0

3.0

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

3. Detection voltage (VDET) vs. Power supply voltage (VDD)

S-1002Cx10

1.030

1.020

1.010

1.000

0.990

0.980

0.970

0.0 2.0 4.0 6.0 8.0 10.0

[V]

V

DET

[V]

Ta = 85

C

Ta = 25

C

Ta =



C

S-1002Cx24

2.430

2.420

2.410

2.400

2.390

2.380

2.370

0.0 2.0 4.0 6.0 8.0 10.0

[V]

V

DET

[V]

Ta = 85

C

Ta = 25

C

Ta =



C

S-1002Cx50

5.050

0.0 2.0 4.0 6.0 8.0 10.0

[V]

V

DET

[V]

5.025

5.000

4.975

4.950

Ta = 85

C

Ta = 25

C

Ta =



C

4. Hysteresis width (VHYS) vs. Power supply voltage (VDD)

S-1002Cx10

0.0 2.0 4.0 6.0 8.0 10.0

[V]

7.0

6.0

5.0

4.0

3.0

HYS

[%]

Ta = 85

C

Ta = 25

C

Ta =



C

S-1002Cx24

0.0 2.0 4.0 6.0 8.0 10.0

[V]

7.0

6.0

5.0

4.0

3.0

HYS

[%]

Ta = 85

C

Ta = 25

C

Ta =



C

S-1002Cx50

0.0 2.0 4.0 6.0 8.0 10.0

VDD [V]

7.0

6.0

5.0

4.0

3.0

VHYS [%]

Ta = 85

C

Ta = 25

C

Ta =



C

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

5. Current consumption (ISS) vs. Power supply voltage (VDD)

S-1002Cx10 Ta = 25°C,

SENSE = VDET(S)  0.1 V (during detection)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx10 Ta = 25°C,

SENSE = VDET(S)  1.0 V (during release)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx24 Ta = 25°C,

SENSE = VDET(S)  0.1 V (during detection)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx24 Ta = 25°C,

SENSE = VDET(S)  1.0 V (during release)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx50 Ta = 25°C,

SENSE = VDET(S)  0.1 V (during detection)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

VDD [V]

0.80

0.60

0.40

0.20

0.00

ISS [A]

S-1002Cx50 Ta = 25°C,

SENSE = VDET(S)  1.0 V (during release)

1.00

0.0 2.0 4.0 6.0 8.0 10.0

VDD [V]

0.80

0.60

0.40

0.20

0.00

ISS [A]

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

6. Current consumption (ISS) vs. SENSE pin input voltage (VSENSE)

S-1002Cx10 Ta = 25°C,

DD = VDET(S)  1.0 V, VSENSE = 0.0 V  10.0 V

1.00

0.0 2.0 4.0 6.0 8.0 10.0

SENSE

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx24 Ta = 25°C,

DD = VDET(S)  1.0 V, VSENSE = 0.0 V  10.0 V

1.00

0.0 2.0 4.0 6.0 8.0 10.0

SENSE

[V]

0.80

0.60

0.40

0.20

0.00

[A]

S-1002Cx50 Ta = 25°C,

DD = VDET(S)  1.0 V, VSENSE = 0.0 V  10.0 V

1.00

0.0 2.0 4.0 6.0 8.0 10.0

SENSE

[V]

0.80

0.60

0.40

0.20

0.00

[A]

7. Current consumption (ISS) vs. Temperature (Ta)

S-1002Cx10 VDD = VDET(S)  1.0 V,

SENSE = VDET(S)  1.0 V (during release)

0.30



40 857550250



Ta [ C]

0.25

0.20

0.15

0.10

0.05

0.00

[A]

S-1002Cx24 VDD = VDET(S)  1.0 V,

SENSE = VDET(S)  1.0 V (during release)

0.30



40 857550250



Ta [ C]

0.25

0.20

0.15

0.10

0.05

0.00

[A]

S-1002Cx50 VDD = VDET(S)  1.0 V,

SENSE = VDET(S)  1.0 V (during release)

0.30

−

40 857550250

−

Ta [ °C]

0.25

0.20

0.15

0.10

0.05

0.00

[µA]

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

8. Nch transistor output current (IOUT) vs. VDS 9. Pch transistor output current (IOUT) vs. VDS

S-1002Nx12 Ta = 25°C,

SENSE = 0.0 V (during detection)

20.0

0.0

0.0 6.0

OUT

[mA]

[V]

5.04.03.02.01.0

15.0

10.0

5.0

= 6.0 V

= 4.8 V

= 3.6 V

= 2.4 V

= 1.2 V

= 0.95 V

S-1002Cx12 Ta = 25°C,

SENSE = VDET(S)  1.0 V (during release)

40.0

0.0

0.0 10.0

OUT

[mA]

[V]

2.0 4.0 6.0 8.0

30.0

20.0

10.0

= 8.4 V

= 1.2 V

= 0.95 V

= 7.2 V

= 6.0 V

= 4.8 V

= 3.6 V

= 2.4 V

10. Nch transistor output current (I

OUT

) vs. Power supply voltage (V

) 11. Pch transistor output current (I

OUT

) vs.



Power supply voltage (V

)

S-1002Nx12 VDS = 0.5 V,

SENSE = 0.0 V (during detection)

4.0

0.0

0.0 10.0

IOUT [mA]

VDD [V]

3.0

2.0

1.0

2.0 4.0 6.0 8.0

Ta = 40C

Ta = 25C

Ta = 85C

S-1002Cx12 VDS = 0.5 V,

SENSE = VDET(S)  1.0 V (during release)

5.0

0.0

0.0 10.0

OUT

[mA]

[V]

2.0 4.0 6.0 8.0

4.0

3.0

2.0

1.0

Ta = 40C

Ta = 25C

Ta = 85C

12. Minimum operation voltage (VOUT) vs. Power supply voltage (VDD)

S-1002Nx10 VSENSE = VDD,

Pull-up to VDD, Pull-up resistance: 100 k

1.8

0.0

0.0 1.6

VOUT [V]

VDD [V]

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

1.41.21.00.80.60.40.2

Ta = 40C

Ta = 25C

Ta = 85C

S-1002Nx10 VSENSE = VDD,

Pull-up to 10 V, Pull-up resistance: 100 k

12.0

0.0

0.0 1.6

VOUT [V]

VDD [V]

1.41.21.00.80.60.40.2

10.0

8.0

6.0

4.0

2.0

Ta = 40C

Ta = 25C

Ta = 85C

13. Minimum operation voltage (VOUT) vs. SENSE pin input voltage (VSENSE)

S-1002Nx10 VDD = 0.95 V,

Pull-up to VDD, Pull-up resistance: 100 k

1.8

0.0

0.0 1.6

OUT

[V]

SENSE

[V]

1.6

1.4

1.2

1.0

0.8

0.6

0.4

0.2

1.41.21.00.80.60.40.2

Ta = 40C

Ta = 25C

Ta = 85C

S-1002Nx10 VDD = 0.95 V,

Pull-up to 10 V, Pull-up resistance: 100 k

12.0

0.0

0.0 1.6

OUT

[V]

SENSE

[V]

1.41.21.00.80.60.40.2

10.0

8.0

6.0

4.0

2.0

Ta = 40C

Ta = 25C

Ta = 85C

Remark V

DS: Drain-to-source voltage of the output transistor

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

14. Dynamic response vs. Output pin capacitance (COUT)

S-1002Cx10 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.001

Output pin capacitance [F]

0.01

0.1

0.10.0001 0.010.001

PHL

PLH

S-1002Cx24 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.001

Output pin capacitance [F]

0.01

0.1

0.10.0001 0.010.001

PHL

PLH

S-1002Cx50 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.001

Output pin capacitance [F]

0.01

0.1

0.10.0001 0.010.001

PLH

PHL

S-1002Nx10 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.01

Output pin capacitance [F]

100

0.1

0.10.0001 0.010.001

PHL

PLH

S-1002Nx24 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.01

Output pin capacitance [F]

100

0.1

0.10.0001 0.010.001

PHL

PLH

S-1002Nx50 Ta = 25°C,

DD = VDET(S)  1.0 V

0.00001

Response time [ms]

0.01

Output pin capacitance [F]

100

0.1

0.10.0001 0.010.001

tPHL

tPLH

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

1 s

PLH

IH*1

SENSE pin

voltage

Output voltage

IL*2

 10%

 90%

PHL

1 s

*1. V

IH = 10 V

*2. VIL = 0.95 V

Figure 32 Test Condition of Response Time

VDD VDD

VSS

OUT

100 k

SENSE

P.G.

Oscilloscope

VDD

VSS

OUT

SENSE

P.G.

Oscilloscope

Figure 33 Test Circuit of Response Time Figure 34 Test Circuit of Response Time

(Nch open-drain output product) (CMOS output product)

Caution The above connection diagram and constant will not guarantee successful operation.

Perform thorough evaluation using the actual application to set the constant.

VOLTAGE DETECTOR WITH SENSE PIN

S-1002 Series Rev.1.1_03

 Application Circuit Examples

1. Microcomputer reset circuits

In microcomputers, when the power supply voltage is lower than the minimum operation voltage, an unspecified

operation may be performed or the contents of the memory register may be lost. When power supply voltage

returns to the normal level, the microcomputer needs to be initialized. Otherwise, the microcomputer may

malfunction after that. Reset circuits to protect microcomputer in the event of current being momentarily switched

off or lowered.

Using the S-1002 Series which has the low minimum operation voltage, the high-accuracy detection voltage and

the hysteresis width, reset circuits can be easily constructed as seen in Figure 35 and Figure 36.

GND

DD1

VDD

VSS

SENSE

OUT Microcomputer

GND

DD1

VDD

VSS

SENSE

OUT Microcomputer

Figure 35 Example of Reset Circuit Figure 36 Example of Reset Circuit

(Nch open-drain output product) (CMOS output product)

Caution The above connection diagram and constant will not guarantee successful operation.

Perform thorough evaluation using the actual application to set the constant.

VOLTAGE DETECTOR WITH SENSE PIN

Rev.1.1_03 S-1002 Series

2. Change of detection voltage

If there is not a product with a specified detection voltage value in the S-1002 Series, the detection voltage can be

changed by using a resistance divider or a diode, as seen in Figure 37 to Figure 40.

In Figure 37 and Figure 38, hysteresis width also changes.

GND

100 k

VSS

OUT

VDD

SENSE

GND

VSS

OUT

VDD

SENSE

Figure 37 Detection voltage change Figure 38 Detection voltage change

when using a resistance divider when using a resistance divider

(Nch open-drain output product) (CMOS output product)

Remark Detection voltage = RA  RB

RB  VDET

Hysteresis width =

RA  RB

RB  VHYS

GND

100 k

VDD

VSS

OUT

SENSE

GND

VDD

VSS

OUT

SENSE

Figure 39 Detection voltage change Figure 40 Detection voltage change

when using a diode when using a diode

(Nch open-drain output product) (CMOS output product)

Remark Detection voltage = Vf1  (VDET)

Caution 1. The above connection diagram and constant will not guarantee successful operation.

Perform thorough evaluation using the actual application to set the constant.

2. Set the constants referring to "2. 1 Error when detection voltage is set externally" in

" Operation".

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

2.9±0.2

1.9±0.2

0.95±0.1

0.4±0.1

0.16 +0.1

-0.06

123

No. MP005-A-P-SD-1.3

MP005-A-P-SD-1.3

SOT235-A-PKG Dimensions

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

ø1.5 +0.1

-0 2.0±0.05

ø1.0 +0.2

-0 4.0±0.1 1.4±0.2

0.25±0.1

3.2±0.2

123

No. MP005-A-C-SD-2.1

MP005-A-C-SD-2.1

SOT235-A-Carrier Tape

Feed direction

4.0±0.1(10 pitches:40.0±0.2)

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

12.5max.

9.0±0.3

ø13±0.2

(60°) (60°)

QTY. 3,000

No. MP005-A-R-SD-1.1

MP005-A-R-SD-1.1

SOT235-A-Reel

Enlarged drawing in the central part

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

0.3 +0.1

-0.05

0.4 +0.1

-0.05

0.05

0.16 +0.1

-0.06

1.3±0.2

2.0±0.2

No. NP004-A-P-SD-2.0

SC82AB-A-PKG Dimensions

NP004-A-P-SD-2.0

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

1.1±0.1

0.2±0.05

4.0±0.1

2.0±0.05

4.0±0.1

2.2±0.2

(0.7)

No. NP004-A-C-SD-3.0

NP004-A-C-SD-3.0

SC82AB-A-Carrier Tape

Feed direction

ø1.05±0.1

ø1.5 +0.1

-0

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

No. NP004-A-C-S1-2.0

NP004-A-C-S1-2.0

SC82AB-A-Carrier Tape

4.0±0.1 2.0±0.1

4.0±0.1 ø1.05±0.1

0.2±0.05

1.1±0.1

Feed direction

2.3±0.15

ø1.5 +0.1

-0

No.

TITLE

UNIT

ANGLE

ABLIC Inc.

QTY. 3,000

NP004-A-R-SD-1.1

SC82AB-A-Reel

No. NP004-A-R-SD-1.1

12.5max.

9.0±0.3

ø13±0.2

(60°) (60°)

Enlarged drawing in the central part

Disclaimers (Handling Precautions)

1. All the information described herein (product data, specifications, figures, tables, programs, algorithms and

application circuit examples, etc.) is current as of publishing date of this document and is subject to change without

notice.

2. The circuit examples and the usages described herein are for reference only, and do not guarantee the success of

any specific mass-production design.

ABLIC Inc. is not liable for any losses, damages, claims or demands caused by the reasons other than the products

described herein (hereinafter "the products") or infringement of third-party intellectual property right and any other

right due to the use of the information described herein.

3. ABLIC Inc. is not liable for any losses, damages, claims or demands caused by the incorrect information described

herein.

4. Be careful to use the products within their ranges described herein. Pay special attention for use to the absolute

maximum ratings, operation voltage range and electrical characteristics, etc.

ABLIC Inc. is not liable for any losses, damages, claims or demands caused by failures and / or accidents, etc. due to

the use of the products outside their specified ranges.

5. Before using the products, confirm their applications, and the laws and regulations of the region or country where they

are used and verify suitability, safety and other factors for the intended use.

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life, or assets (such as medical equipment, disaster prevention systems, security systems, combustion control

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ABLIC, Inc. Do not apply the products to the above listed devices and equipments.

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the products.

9. In general, semiconductor products may fail or malfunction with some probability. The user of the products should

therefore take responsibility to give thorough consideration to safety design including redundancy, fire spread

prevention measures, and malfunction prevention to prevent accidents causing injury or death, fires and social

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The entire system in which the products are used must be sufficiently evaluated and judged whether the products are

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careful when handling these with the bare hands to prevent injuries, etc.

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13. The information described herein contains copyright information and know-how of ABLIC Inc. The information

described herein does not convey any license under any intellectual property rights or any other rights belonging to

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15. This Disclaimers have been delivered in a text using the Japanese language, which text, despite any translations into

the English language and the Chinese language, shall be controlling.

2.4-2019.07