S-19501AFJA-E8T1U4 - Ablic

S-19500/19501 Series

AUTOMOTIVE, 125°C OPERATION,

36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER

OLTAGE REGULATOR WITH RESET FUNCTION

www.ablic.com

The S-19500/19501 Series, developed by using high-withstand voltage CMOS technology, is a low dropout positive

voltage regulator with the watchdog timer and the reset function, which has high-withstand voltage. The monitoring time of

watchdog timer can be adjusted by an external capacitor. Moreover, a voltage detection circuit which monitors the output

voltage is also prepared.

ABLIC Inc. offers a "thermal simulation service" which supports the thermal design in conditions when our power

management ICs are in use by customers. Our thermal simulation service will contribute to reducing the risk in the thermal

design at customers' development stage.

ABLIC Inc. also offers FIT rate calculated based on actual customer usage conditions in order to support customer

functional safety design.

Contact our sales representatives for details.

Caution This product can be used in vehicle equipment and in-vehicle equipment. Before using the product for

these purposes, it is imperative to contact our sales representatives.

 Features

Regulator block

• Output voltage: 3.0 V to 5.3 V, selectable in 0.1 V step

• Input voltage: 4.0 V to 36.0 V

• Output voltage accuracy: ±2.0% (Tj = −40°C to +150°C)

• Dropout voltage: 120 mV typ. (5.0 V output product, IOUT = 100 mA)

• Output current: Possible to output 200 mA (VIN = VOUT(S) + 1.0 V)*1

• Input and output capacitors: A ceramic capacitor of 2.2 μF or more can be used.

• Ripple rejection: 70 dB typ. (f = 100 Hz)

• Built-in overcurrent protection circuit: Limits overcurrent of output transistor.

• Built-in thermal shutdown circuit: Detection temperature 170°C typ.

Detector block

• Detection voltage: 2.6 V to 5.0 V, selectable in 0.1 V step

• Detection voltage accuracy: ±100 mV (Tj = −40°C to +150°C)

• Hysteresis width: 0.12 V min.

• Release delay time is adjustable*2: 18 ms typ. (CDLY = 47 nF)

Watchdog timer block

• Watchdog activation current is adjustable: 1.5 mA typ. (WADJ pin is open)

• Watchdog trigger time is adjustable*2: 43 ms typ. (CDLY = 47 nF)

• Product type is selectable: S-19500 Series (Product with WEN pin (Output: WO / RO pin))

S-19501 Series (Product without WEN pin (Output: WO pin and RO pin))

• Autonomous watchdog operation function: Watchdog timer operates due to detection of load current.

• Watchdog mode: Time-out mode

Overall

• Current consumption: 60 μA typ. (IOUT = 0 mA, During the watchdog timer deactivation)

75 μA typ. (IOUT ≤ 5 mA, During the watchdog timer activation)

• Operation temperature range: Ta = −40°C to +125°C

• Lead-free (Sn 100%), halogen-free

• Withstand 45 V load dump

• AEC-Q100 qualified*3

*1. Please make sure that the loss of the IC will not exceed the power dissipation when the output current is large.

*2. The release delay time and the watchdog trigger time can be adjusted by connecting CDLY to the DLY pin.

*3. Contact our sales representatives for details.

 Applications

• Constant-voltage power supply for automotive electric component, monitoring of microcontroller

 Package

• HSOP-8A

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

 Block Diagrams

1. S-19500 Series (Product with WEN pin)

VIN

VSS

WADJ

VOUT

DLY

WO / RO

WEN

Voltage

detection

circuit

WDT

circuit

−

Thermal

shutdown

circuit

Overcurrent protection circuit

Reference

voltage circuit

Reference

voltage

circuit

Figure 1

2. S-19501 Series (Product without WEN pin)

VIN

VSS

WADJ

VOUT

DLY

Voltage

detection

circuit

WDT

circuit

−

Thermal

shutdown

circuit

Overcurrent protection circuit

Reference

voltage circuit

Reference

voltage

circuit

Figure 2

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 AEC-Q100 Qualified

This IC supports AEC-Q100 for the operation temperature grade 1.

Contact our sales representatives for details of AEC-Q100 reliability specification.

 Product Name Structure

1. Product name

S-1950 x A x x A - E8T1 U 4

Package abbreviation and IC packing specifications*1

E8T1: HSOP-8A, Tape

Environmental code

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

Operation temperature

A: Ta = −40°C to +125°C

Product type

0: S-19500 Series (Product with WEN pin)

1: S-19501 Series (Product without WEN pin)

Detection voltage*2

F to Z, 0 to 5

Output voltage*2

C to Z, 0, 1

*1. Refer to the tape drawing.

*2. Refer to "2. Product option list".

2. Product option list

Table 1 Output Voltage Table 2 Detection Voltage

Set Output

Voltage Symbol Set Output

Voltage Symbol Set Detection

Voltage Symbol

5.3 V C 4.1 V Q 5.0 V F 3.7 V U

5.2 V D 4.0 V R 4.9 V G 3.6 V V

5.1 V E 3.9 V S 4.8 V H 3.5 V W

5.0 V F 3.8 V T 4.7 V J 3.4 V X

4.9 V G 3.7 V U 4.6 V K 3.3 V Y

4.8 V H 3.6 V V 4.5 V L 3.2 V Z

4.7 V J 3.5 V W 4.4 V M 3.1 V 0

4.6 V K 3.4 V X 4.3 V N 3.0 V 1

4.5 V L 3.3 V Y 4.2 V P 2.9 V 2

4.4 V M 3.2 V Z 4.1 V Q 2.8 V 3

4.3 V N 3.1 V 0 4.0 V R 2.7 V 4

4.2 V P 3.0 V 1 3.9 V S 2.6 V 5

3.8 V T

Remark Set output voltage ≥ Set detection voltage + 0.3 V

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

3. Package

Table 3 Package Drawing Codes

Package Name Dimension Tape Reel Land

HSOP-8A FH008-A-P-SD FH008-A-C-SD FH008-A-R-SD FH008-A-L-SD

4. Product name list

4. 1 S-19500 Series (Product with WEN pin)

Table 4

Output Voltage (VOUT) Detection Voltage (−VDET) HSOP-8A

3.1 V ± 2.0% 2.8 V ± 0.1 V S-19500A03A-E8T1U4

3.3 V ± 2.0% 2.8 V ± 0.1 V S-19500AY3A-E8T1U4

3.3 V ± 2.0% 3.0 V ± 0.1 V S-19500AY1A-E8T1U4

5.0 V ± 2.0% 2.8 V ± 0.1 V S-19500AF3A-E8T1U4

5.0 V ± 2.0% 4.2 V ± 0.1 V S-19500AFPA-E8T1U4

5.0 V ± 2.0% 4.5 V ± 0.1 V S-19500AFLA-E8T1U4

5.0 V ± 2.0% 4.6 V ± 0.1 V S-19500AFKA-E8T1U4

5.0 V ± 2.0% 4.7 V ± 0.1 V S-19500AFJA-E8T1U4

5.3 V ± 2.0% 5.0 V ± 0.1 V S-19500ACFA-E8T1U4

Remark Please contact our sales representatives for products other than the above.

4. 2 S-19501 Series (Product without WEN pin)

Table 5

Output Voltage (VOUT) Detection Voltage (−VDET) HSOP-8A

3.3 V ± 2.0% 2.8 V ± 0.1 V S-19501AY3A-E8T1U4

5.0 V ± 2.0% 2.9 V ± 0.1 V S-19501AF2A-E8T1U4

5.0 V ± 2.0% 3.5 V ± 0.1 V S-19501AFWA-E8T1U4

5.0 V ± 2.0% 4.2 V ± 0.1 V S-19501AFPA-E8T1U4

5.0 V ± 2.0% 4.5 V ± 0.1 V S-19501AFLA-E8T1U4

5.0 V ± 2.0% 4.6 V ± 0.1 V S-19501AFKA-E8T1U4

5.0 V ± 2.0% 4.7 V ± 0.1 V S-19501AFJA-E8T1U4

Remark Please contact our sales representatives for products other than the above.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 Pin Configuration

1. HSOP-8A

Bottom view

Top view

Figure 3

Table 6 S-19500 Series (Product with WEN pin)

Pin No. Symbol Description

1 VOUT Voltage output pin (Regulator block)

2 WADJ Connection pin for watchdog activation

threshold current adjustment resisto

3 VSS GND pin

4 DLY Connection pin for release delay time and

monitoring time adjustment capacito

5 WO / RO*2 WO Watchdog output pin

RO Reset output pin

6 WEN Watchdog enable pin

7 WI Watchdog input pin

8 VIN Voltage input pin (Regulator block)

Table 7 S-19501 Series (Product without WEN pin)

Pin No. Symbol Description

1 VOUT Voltage output pin (Regulator block)

2 WADJ Connection pin for watchdog activation

threshold current adjustment resisto

3 VSS GND pin

4 DLY Connection pin for release delay time and

monitoring time adjustment capacito

5 RO Reset output pin

6 WO Watchdog output pin

7 WI Watchdog input pin

8 VIN Voltage input pin (Regulator block)

*1. Connect the heat sink of backside at shadowed area to the board, and set electric potential GND.

However, do not use it as the function of electrode.

*2. The WO / RO pin combines the watchdog output pin and the reset output pin.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

 Absolute Maximum Ratings

Table 8

(Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Absolute Maximum Rating Unit

VIN pin voltage VIN VSS − 0.3 to VSS + 45.0 V

VOUT pin voltage VOUT VSS − 0.3 to VIN + 0.3 ≤ VSS + 7.0 V

DLY pin voltage VDLY VSS − 0.3 to VOUT + 0.3 ≤ VSS + 7.0 V

RO pin voltage VRO VSS − 0.3 to VOUT + 0.3 ≤ VSS + 7.0 V

WADJ pin voltage VWADJ VSS − 0.3 to VIN + 0.3 ≤ VSS + 7.0 V

WEN pin voltage VWEN VSS − 0.3 to VSS + 7.0 V

WI pin voltage VWI VSS − 0.3 to VSS + 7.0 V

WO pin voltage VWO VSS − 0.3 to VOUT + 0.3 ≤ VSS + 7.0 V

WO / RO pin voltage VWO / RO VSS − 0.3 to VOUT + 0.3 ≤ VSS + 7.0 V

Output current IOUT 260 mA

Junction temperature Tj −40 to +150 °C

Operation ambient temperature Topr −40 to +125 °C

Storage temperature Tstg −40 to +150 °C

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.

 Thermal Resistance Value

Table 9

Item Symbol Condition Min. Typ. Max. Unit

Junction-to-ambient thermal resistance*1 θJA HSOP-8A

Board A − 104 − °C/W

Board B − 74 − °C/W

Board C − 39 − °C/W

Board D − 37 − °C/W

Board E − 31 − °C/W

*1. Test environment: compliance with JEDEC STANDARD JESD51-2A

Remark Refer to " Power Dissipation" and "Test Board" for details.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 Recommended Operation Conditions

Table 10

Item Symbol Condition Min. Typ. Max. Unit

VIN pin voltage VIN

− 4.0 − 36.0 V

When using autonomous

watchdog operation function*1

VOUT(S)

+ 1.0 − 36.0 V

VOUT pin voltage VOUT

Detector block 1.0 − − V

Watchdog timer block +VDET − − V

Watchdog input voltage "H"*2 V

WIH − 2 − − V

Watchdog input voltage "L"*2 V

WIL − − −

0.8 V

Watchdog input "H" time*2 t

high VWI ≥ VWIH 5.0 − − μs

Watchdog input "L" time*2 t

Iow VWI ≤ VWIL 5.0 − − μs

Slew rate*2 dVWI

dt VWI = VWIL + (VWIH − VWIL) × 0.1

to VWIL + (VWIH − VWIL) × 0.9 1 − − V/μs

Watchdog input frequency fWI Duty ratio 50% − −

0.2 MHz

WEN pin input voltage "H" VWENH S-19500 Series 2.0 − VOUT(S) V

WEN pin input voltage "L" VWENL S-19500 Series 0 − 0.8 V

Input capacitance CIN − 2.2 − − μF

Output capacitance CL − 2.2 − − μF

Equivalent series resistance RESR Output capacito

(CL) − − 10 Ω

Release delay time and monitoring

time adjustment capacitance

CDLY − 1 47 − nF

Watchdog activation threshold

current adjustment resistance*4 RWADJ,ext Connected to WADJ pin 10 − − kΩ

External pull-up resistances for

output pins

RextW S-19501 Series Connected to

WO pin 3 − − kΩ

RextR

S-19500 Series Connected to

WO / RO pin 3 − − kΩ

S-19501 Series Connected to

RO pin 3 − − kΩ

*1. Refer to "3. Watchdog timer block" in " Operation" for the autonomous watchdog operation function.

*2. When inputting a rising edge that satisfies the condition of Figure 4 to the WI pin, the watchdog timer detects a

trigger.

The signal input from the monitored object by the watchdog timer should satisfy the condition of Figure 4.

*3. Refer to "2. Release delay time and monitoring time adjustment capacitor (CDLY)" in " Selection of

External Parts" for the details.

*4. Refer to "3. Watchdog activation threshold current adjustment resistor (RWADJ,ext)" in " Selection of

External Parts" for the details.

WIH

WIL

low

Figure 4

Caution 1. Generally a series regulator may cause oscillation, depending on the selection of external parts.

Confirm that no oscillation occurs in the actual application using capacitors that meet the above

CIN, CL, and RESR.

2. Define the external pull-up resistance by sufficient evaluation including the temperature

characteristics under the actual usage conditions.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

 Electrical Characteristics

1. Regulator block

Table 11

(VIN = 13.5 V, Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max.

Unit Test

Circuit

Output voltage*1 VOUT(E) VIN = 13.5 V, IOUT = 30 mA VOUT(S)

− 2.0% VOUT(S) VOUT(S)

+ 2.0% V 1

Output current*2 I

OUT VIN ≥ VOUT(S) + 1.0 V 200*7 − −

mA 2

Dropout voltage*3 V

drop

IOUT = 30 mA, Ta = +25°C,

VOUT(S) = 3.0 V to 5.3 V − 40 50

mV 1

IOUT = 100 mA, Ta = +25°C,

VOUT(S) = 3.0 V to 5.3 V − 120 200

mV 1

Line regulation*4 ΔVOUT1

ΔVIN • VOUT VOUT(S) + 1.0 V ≤ VIN ≤ 36.0 V,

IOUT = 30 mA, Ta = +25°C − 0.02 0.10

%/V 1

Load regulation*5 ΔVOUT2 VIN = 13.5 V, 100 μA ≤ IOUT ≤ 100 mA,

Ta = +25°C − 20 40

mV 1

Input voltage VIN − 4.0 − 36.0 V −

Ripple rejection |RR| VIN = 13.5 V, IOUT = 30 mA,

f = 100 Hz, ΔVrip = 1.0 Vp-p − 70 − dB 3

Limit current*6 I

LIM VIN = VOUT(S) + 1.0 V, VOUT = 1.2 V,

Ta = +25°C 260 500 700 mA 2

Short-circuit current Ishort VIN = 13.5 V, VOUT = 0 V, Ta = +25°C 30 60 80

mA 2

Thermal shutdown

detection

temperature

TSD Junction temperature − 170 − °C −

Thermal shutdown

release temperature TSR Junction temperature − 135 − °C −

*1. The accuracy is guaranteed when the input voltage, output current, and temperature satisfy the conditions listed

above.

OUT(S): Set output voltage

OUT(E): Actual output voltage

*2. The output current when increasing the output current gradually until the output voltage has reached the value of

95% of VOUT(E).

*3. The difference between input voltage (VIN1) and the output voltage when decreasing input voltage (VIN) gradually

until the output voltage has dropped out to the value of 98% of output voltage (VOUT3).

Vdrop: VIN1 − (VOUT3 × 0.98)

VOUT3: Output voltage when VIN = VOUT(S) + 1.0 V

*4. The dependency of the output voltage against the input voltage. The value shows how much the output voltage

changes due to a change in the input voltage while keeping output current constant.

*5. The dependency of the output voltage against the output current. The value shows how much the output voltage

changes due to a change in the output current while keeping input voltage constant.

*6. The current limited by overcurrent protection circuit.

*7. Due to limitation of the power dissipation, this value may not be satisfied. Attention should be paid to the power

dissipation when the output current is large.

This specification is guaranteed by design.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

2. Detector block

Table 12

(VIN = 13.5 V, Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Detection voltage*1 −VDET − −VDET(S)

− 0.1 −VDET(S) −VDET(S)

+ 0.1 V 4

Hysteresis width*2 V

HYS − 120 150 − mV 4

Reset output voltage "H" VROH − VOUT(S)

× 0.9 − −

V 4

Reset output voltage "L" VROL VOUT ≥ 1.0 V, RextR ≥ 3 kΩ,

Connected to VOUT pin − 0.2 0.4 V 4

Reset pull-up resistance RRO VOUT pin internal resistance 20 30 45 kΩ −

Reset output current IRO VRO = 0.4 V, VOUT = −VDET(S) − 0.1 V 3.0 − −

mA 5

Release delay time*3 t

rd C

DLY = 47 nF 11 18 25 ms 4

Reset reaction time*4 t

rr C

DLY = 47 nF − −

50*5 μs 4

*1. The voltage at which the output of the RO pin turns to "L". The accuracy is guaranteed when the input voltage and

temperature satisfy the listed conditions above.

−VDET(S): Set detection voltage

−VDET: Actual detection voltage

*2. The voltage difference between the detection voltage (−VDET) and the release voltage (+VDET). The relation between the

actual output voltage (VOUT(E)) of the regulator block and the actual release voltage (+VDET = −VDET + VHYS) of the

detector block is as follows.

OUT(E) > +VDET

*3. The time from when VOUT exceeds +VDET to when the RO pin output inverts (Refer to Figure 5). This value changes

according to the release delay time and monitoring time adjustment capacitor (CDLY).

The time period from when VOUT changes to +VDET → VOUT(S) to when VRO reaches VOUT / 2.

*4. The time from when VOUT falls below −VDET to when the RO pin output inverts (Refer to Figure 6). The time period from

when VOUT changes to VOUT(S) → −VDET to when VRO reaches VOUT / 2.

*5. The guaranteed value when the watchdog timer is deactivated. trr may shorten since the discharge operation of CDLY

may be performed while the watchdog timer is activated.

OUT

DET

OUT

−V

DET

Figure 5 Release Delay Time Figure 6 Reset Reaction Time

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

3. Watchdog timer block

3. 1 S-19500 Series (Product with WEN pin)

Table 13

(VIN = 13.5 V, Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Watchdog activation threshold

current IO,WDact WADJ pin is open 1.1 1.5 1.9 mA 6

Watchdog deactivation

threshold current IO,WDdeact WADJ pin is open − 1.3 − mA 6

Watchdog activation hysteresis

current IO,WDhys WADJ pin is open 0.1 0.2 − mA 6

Watchdog activation threshold

voltage VWADJ,th − 1.28 1.35 1.45 V 7

WADJ pin current ratio IOUT

IWADJ V

WADJ = 0 V, IOUT = 10 mA − 750 − −

WADJ pin internal resistance RWADJ,int − 490 650 845

kΩ −

Watchdog output pulse period*1 t

WD,p CDLY = 47 nF 38 54 72 ms 6

Watchdog output "L" time*2 t

WD,L VOUT > −VDET, CDLY = 47 nF

Watchdog timer is activated 6 11 16 ms 6

Watchdog trigger time*3 t

WI,tr C

DLY = 47 nF 32 43 56 ms 6

WEN pin input voltage "H" VSH − 2 − − V 8

WEN pin input voltage "L" VSL − − −

0.8 V 8

WEN pin input current "H" ISH V

WEN = VOUT(S) − 0.1 1

A 8

WEN pin input current "L" ISL V

WEN = 0 V −0.1 − 0.1 μA 8

*1. The period of the continuous rectangular wave that appears in the WO / RO pin when the watchdog timer repeats

the detection of a time-out (Refer to Figure 7). It is calculated by using the following equation.

WD,p = tWI,tr + tWD,L

*2. The time when the WO / RO pin continues "L" after the watchdog timer detects a time-out (Refer to Figure 7).

*3. The time from when the watchdog timer initiates the detection of a trigger signal to when a time-out is detected and

the WO / RO pin output changes to "L" (Refer to Figure 7). This value changes according to CDLY.

This is the guaranteed value when VOUT increases to +VDET or higher and the discharge operation of CDLY due to the

detector operation is not performed. The discharge operation of CDLY may be performed when VOUT decreases to

−VDET or lower. At that time, tWI,tr, tWD,L and tWD,p may be changed.

WI,tr

DLY

DWL

WD,L

WO / RO

WD,p

Figure 7

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

3. 2 S-19501 Series (Product without WEN pin)

Table 14

(VIN = 13.5 V, Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Watchdog activation threshold

current IO,WDact WADJ pin is open 1.1 1.5 1.9 mA 6

Watchdog deactivation

threshold current IO,WDdeact WADJ pin is open − 1.3 − mA 6

Watchdog activation hysteresis

current IO,WDhys WADJ pin is open 0.1 0.2 − mA 6

Watchdog activation threshold

voltage VWADJ,th − 1.28 1.35 1.45 V 7

WADJ pin current ratio IOUT

IWADJ V

WADJ = 0 V, IOUT = 10 mA − 750 − −

WADJ pin inte

nal resistance RWADJ,int − 490 650 845 kΩ −

Watchdog output voltage "H" VWOH − VOUT(S)

× 0.9 − − V 11

Watchdog output voltage "L" VWOL RextW ≥ 3 kΩ,

Connected to VOUT pin − 0.2 0.4 V 11

Watchdog pull-up resistance RWO VOUT pin internal resistance 20 30 45 kΩ −

Watchdog output current IWO VWO = 0.4 V,

VOUT = −VDET(S) − 0.1 V 3.0 − − mA 12

Watchdog output pulse

period*1 tWD,p C

DLY = 47 nF 38 54 72 ms 6

Watchdog output "L" time*2 t

WD,L VOUT > −VDET, CDLY = 47 nF

Watchdog time

is activated 6 11 16 ms 6

Watchdog trigger time*3 t

WI,tr C

DLY = 47 nF 32 43 56 ms 6

*1. The period of the continuous rectangular wave that appears in the WO pin when the watchdog timer repeats the

detection of a time-out (Refer to Figure 8). It is calculated by using the following equation.

WD,p = tWI,tr + tWD,L

*2. The time when the WO pin continues "L" after the watchdog timer detects a time-out (Refer to Figure 8).

*3. The time from when the watchdog timer initiates the detection of a trigger signal to when a time-out is detected and

the WO pin output changes to "L" (Refer to Figure 8). This value changes according to CDLY.

This is the guaranteed value when VOUT increases to +VDET or higher and the discharge operation of CDLY due to the

detector operation is not performed. The discharge operation of CDLY may be performed when VOUT decreases to

−VDET or lower. At that time, tWI,tr, tWD,L and tWD,p may be changed.

WI,tr

DLY

DWL

WD,L

WD,p

Figure 8

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

4. Overall

Table 15

(VIN = 13.5 V, Tj = −40°C to +150°C unless otherwise specified)

Item Symbol Condition Min. Typ. Max. Unit

Test

Circuit

Current consumption

during operation ISS1

IOUT ≤ 5 mA, WADJ pin is open,

during watchdog timer activation,

WO pin = "H"

− 75 115 μA 9

IOUT = 50 mA, WADJ pin is open,

during watchdog timer activation,

WO pin = "H"

− 80 125 μA 9

IOUT = 200 mA, WADJ pin is open,

during watchdog timer activation,

WO pin = "H"

− 100 150 μA 9

Current consumption

during watchdog timer

deactivation

ISS2

IOUT = 0 mA,

during watchdog timer deactivation − 60 95 μA 10

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 Test Circuits

1. S-19500 Series (Product with WEN pin)

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

Figure 9 Test Circuit 1 Figure 10 Test Circuit 2

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

V +

extR

Figure 11 Test Circuit 3 Figure 12 Test Circuit 4

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

V +

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

Figure 13 Test Circuit 5 Figure 14 Test Circuit 6

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

WADJ

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

V R

Figure 15 Test Circuit 7 Figure 16 Test Circuit 8

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

WO / RO pin outputs "H".

VIN

VSS

WO / RO

WEN

VOUT

DLY WADJ

+ A

Figure 17 Test Circuit 9 Figure 18 Test Circuit 10

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S-19500/19501 Series Rev.1.7_00

2. S-19501 Series (Product without WEN pin)

VIN

VSS

VOUT

DLY WADJ

+ A

VIN

VSS

VOUT

DLY WADJ

+ A

Figure 19 Test Circuit 1 Figure 20 Test Circuit 2

VIN

VSS

VOUT

DLY WADJ

VIN

VSS

VOUT

DLY WADJ

V +

extR

Figure 21 Test Circuit 3 Figure 22 Test Circuit 4

VIN

VSS

VOUT

DLY WADJ

VIN

VSS

VOUT

DLY WADJ

+ A

Figure 23 Test Circuit 5 Figure 24 Test Circuit 6

VIN

VSS

VOUT

DLY WADJ

+ A

WADJ

VIN

VSS

VOUT

DLY WADJ

+ A

WO pin outputs "H".

Figure 25 Test Circuit 7 Figure 26 Test Circuit 8

VIN

VSS

VOUT

DLY WADJ

+ A

VIN

VSS

VOUT

DLY WADJ +

extW

Figure 27 Test Circuit 9 Figure 28 Test Circuit 10

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Rev.1.7_00 S-19500/19501 Series

VIN

VSS

VOUT

DLY WADJ

V +

Figure 29 Test Circuit 11

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S-19500/19501 Series Rev.1.7_00

 Standard Circuits

1. S-19500 Series (Product with WEN pin)

IN*1

L*2

Input Output

GND

Single GND

VIN

VSS

WO / RO

extR*5

WADJ,ext*4

DLY*3

WEN

VOUT

DLY WADJ

Figure 30

2. S-19501 Series (Product without WEN pin)

IN*1

L*2

Input Output

GND

Single GND

VIN

VSS

extR*5

WADJ,ext*4

DLY*3

VOUT

DLY WADJ

extW*5

Figure 31

*1. C

IN is a capacitor for stabilizing the input.

*2. C

L is a capacitor for stabilizing the output. A ceramic capacitor of 2.2 μF or more can be used.

*3. C

DLY is the release delay time and monitoring time adjustment capacitor.

*4. R

WADJ,ext is the watchdog activation threshold current adjustment resistor.

*5. R

extR and RextW are the external pull-up resistors for the reset output pin and the watchdog output pin,

respectively. Connection of the external pull-up resistor is not absolutely essential since the

S-19500/19501 Series has a built-in pull-up resistor.

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

thorough evaluation using an actual application to set the constants.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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 Selection of External Parts

1. Input and output capacitors (CIN, CL)

The S-19500/19501 Series requires CL between the VOUT pin and the VSS pin for phase compensation. Operation

is stabilized by a ceramic capacitor with an output capacitance of 2.2 μF or more over the entire temperature range.

When using an OS capacitor, a tantalum capacitor, or an aluminum electrolytic capacitor, the capacitance must be

2.2 μF or more, and the ESR must be 10 Ω or less.

The values of output overshoot and undershoot, which are transient response characteristics, vary depending on the

value of the output capacitor.

The required value of capacitance for the input capacitor differs depending on the application.

Caution Define the capacitance of CIN and CL by sufficient evaluation including the temperature

characteristics under the actual usage conditions.

2. Release delay time and monitoring time adjustment capacitor (CDLY)

In the S-19500/19501 Series, the release delay time and monitoring time adjustment capacitor (CDLY) is necessary

between the DLY pin and the VSS pin to adjust the release delay time (trd) of the detector and the monitoring time of

the watchdog timer.

The set release delay time (trd(S)), the set watchdog trigger time (tWI,tr(S)), the set watchdog output "L" time (tWD,L(S))

and the set watchdog output pulse period (tWD,p(S)) are calculated by using following equations, respectively.

The release delay time (trd), the watchdog trigger time (tWI,tr), the watchdog output "L" time (tWD,L) and the watchdog

output pulse period (tWD,p) at the time of the condition of CDLY = 47 nF are shown in " Electrical Characteristics".

trd(S) [ms] = trd [ms] × CDLY [nF]

47 [nF]

tWI,tr(S) [ms] = tWI,tr [ms] × CDLY [nF]

47 [nF]

tWD,L(S) [ms] = tWD,L [ms] × CDLY [nF]

47 [nF]

tWD,p(S) [ms] = tWI,tr(S) [ms] + tWD,L(S) [ms]

Caution 1. The above equations will not guarantee successful operation. Perform thorough evaluation including

the temperature characteristics using an actual application to set the constants.

2. Mounted board layout should be made in such a way that no current flows into or flows from the DLY

pin since the impedance of the DLY pin is high, otherwise correct delay time and monitoring time may

not be provided.

3. Select CDLY whose leakage current can be ignored against the built-in constant current (5.0 μA typ.).

The leakage current may cause deviation in delay time and monitoring time. When the leakage

current is larger than the built-in constant current, no release takes place.

4. Deviations of CDLY are not included in the equations mentioned above. Be sure to determine the

constants considering the deviation of CDLY to be used.

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3. Watchdog activation threshold current adjustment resistor (RWADJ,ext)

In the S-19500/19501 Series, the watchdog activation threshold current adjustment resistor (RWADJ,ext) can be

connected between the WADJ pin and the VSS pin to adjust the watchdog timer activation threshold current.

The set watchdog activation threshold current (IO,WDact(S)), the set watchdog deactivation threshold current

(IO,WDdeact(S)) and the set watchdog activation hysteresis current (IO,WDhys(s)) are calculated by using following

equations, respectively.

The watchdog activation threshold current (IO,WDact), the watchdog deactivation threshold current (IO,WDdeact) and the

watchdog activation hysteresis current (IO,WDhys) when the WADJ pin is open are shown in " Electrical

Characteristics".

IO,WDact(S) [mA] = IO,WDact [mA] × 











1 + RWADJ,int [kΩ]

RWADJ,ext [kΩ]

IO,WDdeact(S) [mA] = IO,WDdeact [mA] × 











1 + RWADJ,int [kΩ]

RWADJ,ext [kΩ]

IO,WDhys(S) [mA] = IO,WDact(S) [mA] − IO,WDdeact(S) [mA]

Caution 1. The above equations will not guarantee successful operation. Perform thorough evaluation including

the temperature characteristics using an actual application to set the constants.

2. Mounted board layout should be made in such a way that no current flows into or flows from the

WADJ pin since the impedance of the WADJ pin is high, otherwise correct IO,WDact and IO,WDdeact may

not be provided.

3. Refer to "3. 2 Autonomous watchdog operation function (Output current detection circuit)" in

" Operation" for the details.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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 Operation

1. Regulator block

1. 1 Basic operation

Figure 32 shows the block diagram of the regulator in the S-19500/19501 Series.

The error amplifier compares the reference voltage (Vref) with feedback voltage (Vfb), which is the output voltage

resistance-divided by feedback resistors (Rs and Rf). It supplies the gate voltage necessary to maintain the

constant output voltage which is not influenced by the input voltage and temperature change, to the output

transistor.

VOUT

VSS

VIN

Error

amplifier

Current

supply

Vref

Vfb

−

Reference voltage

circuit

*1. Parasitic diode

Figure 32

1. 2 Output transistor

In the S-19500/19501 Series, a low on-resistance P-channel MOS FET is used as the output transistor.

Be sure that VOUT does not exceed VIN + 0.3 V to prevent the voltage regulator from being damaged due to

reverse current flowing from the VOUT pin through a parasitic diode to the VIN pin, when the potential of VOUT

became higher than VIN.

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1. 3 Overcurrent protection circuit

The S-19500/19501 Series includes an overcurrent protection circuit which having the characteristics shown in

"1. 1 Output voltage vs. Output current (When load current increases) (Ta = +25°C)" of "1. Regulator

block" in " Characteristics (Typical Data)", in order to limit an excessive output current and overcurrent of the

output transistor due to short-circuiting between the VOUT pin and the VSS pin. The current when the output pin

is short-circuited (Ishort) is internally set at 60 mA typ., and the load current when short-circuiting is limited based

on this value. The output voltage restarts regulating if the output transistor is released from overcurrent status.

Caution This overcurrent protection circuit does not work as for thermal protection. If this IC long keeps

short circuiting, pay attention to the conditions of input voltage and load current so that, under

the usage conditions including short circuit, the loss of the IC will not exceed power dissipation.

1. 4 Thermal shutdown circuit

The S-19500/19501 Series has a thermal shutdown circuit to limit self-heating. When the junction temperature

rises to 170°C typ., the thermal shutdown circuit operates to stop regulating. After that, when the junction

temperature drops to 135°C typ., the thermal shutdown circuit is released to restart regulating.

Due to self-heating of the S-19500/19501 Series, if the thermal shutdown circuit starts operating, it stops

regulating so that the output voltage drops. For this reason, self-heating is limited and the IC's temperature drops.

When the temperature drops, the thermal shutdown circuit is released to restart regulating, thus self-heating is

generated again due to rising of the output voltage. Repeating this procedure makes the waveform of the VOUT

pin output into a pulse-like form. This phenomenon continues unless decreasing either or both of the input

voltage and the output current in order to reduce the internal power consumption, or decreasing the ambient

temperature. Note that the product may suffer physical damage such as deterioration if the above phenomenon

occurs continuously.

Table 16

Thermal Shutdown Circuit VOUT Pin Voltage

Detect: 170°C typ.*1 VSS level

Release: 135°C typ.*1 Set value

*1. Junction temperature

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2. Detector block

2. 1 Basic operation

(1) When the output voltage (VOUT) of the regulator is release voltage (+VDET) of the detector or higher, the Nch

transistor (N1 and N2) are turned off and "H" is output to the RO pin. Since the Pch transistor (P1) is turned on,

the input voltage to the comparator (C1) is RB • VOUT

RA + RB .

(2) Even if VOUT decreases to +VDET or lower, "H" is output to the RO pin when VOUT is the detection voltage (−VDET)

or higher. When VOUT decreases to −VDET (point A in Figure 34) or lower, N1 which is controlled by C1 is turned

on, and CDLY is discharged. If the DLY pin voltage (VDLY) decreases to the lower reset timing threshold voltage

(VDRL) or lower, N2 of output stage of C2 is turned on, and then "L" is output to the RO pin. At this time, P1 is

turned off, and the input voltage to C1 is RB • VOUT

RA + RB + RC .

(3) If VOUT further decreases to the IC's minimum operation voltage or lower, the RO pin output is "H".

(4) When VOUT increases to the IC's minimum operation voltage or higher, "L" is output to the RO pin. Moreover,

even if VOUT exceeds −VDET, the output is "L" when VOUT is lower than +VDET.

(5) When VOUT increases to +VDET (point B in Figure 34) or higher, N1 is turned off and CDLY is charged. N2 is

turned off if VDLY increases to the upper timing threshold voltage (VDU) or higher, and "H" is output to the RO

pin.

VOUT

VSS

DLY

−

Reference

volta

e circuit

−

DLY

Figure 33 Operation of Detector Block

Hysteresis width

HYS

)

B V

OUT

Minimum operation voltage

RO pin output

OUT

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

Release voltage (+V

DET

)

Detection voltage (−V

DET

)

Figure 34 Timing Chart of Detector Block

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2. 2 Delay circuit

When the output voltage (VOUT) of the regulator rises under the status that "L" is output to the RO pin, the reset

release signal is output to the RO pin later than when VOUT becomes +VDET. The release delay time (trd) changes

according to CDLY. Refer to "2. Release delay time and monitoring time adjustment capacitor (CDLY)" in "

Selection of External Parts" for details.

In addition, if the time from when VOUT decreases to −VDET or lower to when VOUT increases to +VDET or higher is

significantly shorter compared to the length of the reset reaction time (trr), VDLY may not decrease to VDRL or lower.

In that case, "H" output remains in the RO pin. Refer to "2. 9 Reset reaction time vs. Release delay time and

monitoring time adjustment capacitance" in " Characteristics (Typical Data)" for the details.

Caution Since trd depends on the charge time of CDLY, trd may be shorter than the set value if the charge

operation is initiated under the condition that a residual electric charge is left in CDLY.

2. 3 Output circuit

Since the RO pin has a built-in resistor to pull up to the VOUT pin internally, the RO pin can output a signal

without an external pull-up resistor

Do not connect to the pin other than VOUT pin when connecting an external pull-up resistor.

In the S-19500 Series, the reset output pin and the watchdog output pin are prepared as the WO / RO pin.

The output level of the WO / RO pin is applied by the AND logic of the reset output pin and the watchdog output

pin.

Example: When the WO pin is "L" and the RO pin is "H", the WO / RO pin is "L".

In the S-19501 Series, the reset output pin is prepared as the RO pin.

Caution Define the external pull-up resistance by sufficient evaluation including the temperature

characteristics under the actual usage conditions.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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3. Watchdog timer block

3. 1 Basic operation

The watchdog timer operates as follows during monitoring operation.

(1) When the WO pin outputs "H", CDLY is discharged by an internal constant current source, and the DLY pin

voltage (VDLY) decreases. The watchdog timer detects a trigger and the CDLY is charged by an internal constant

current source if a rising edge is input to the WI pin from a monitored object by the watchdog timer, and then

VDLY rises. The discharge operation is restarted if VDLY reaches the upper timing threshold voltage (VDU), and

VDLY decreases again. By inputting a rising edge to the WI pin again during the discharge operation, the similar

operation is repeated. At this time, the WO pin outputs "H" continuously.

(2) The watchdog timer does not detect a trigger if the rising edge is not input to the WI pin from a monitored object

by the watchdog timer when the CDLY is discharged and VDLY decreases. The WO pin outputs "L" if the

discharge operation continues not detecting a trigger when VDLY reaches the lower watchdog timing threshold

voltage (VDWL). This operation is called the time-out detection.

(3) After the time-out detection, CDLY is charged while the WO pin outputs "L", and VDLY increases. The WO pin

outputs "H" and restarts the discharge operation if VDLY reaches VDU.

(4) By the operation of (3), a monitored object by the watchdog timer is reset. If a rising edge is input to the WI pin

again, the operation similar to (1) is continued since the watchdog timer detects a trigger.

(5) After the operation of (3), if the status in which a rising edge is not input to the WI pin continues, the watchdog

timer repeats the operation of (5) → (3) → (5) →...

DLY

Reference

voltage circuit

−

WDT input circuit

VOUT

WEN Charge-

discharge

control

circuit

Output current

detection circuit

WDT enable circuit

VSS

VIN

WADJ

DLY

Figure 35

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

The time period from when the watchdog timer detects a trigger to when it detects a time-out (tWD,TO) is indicated

as the following expression. Figure 36 shows a timing chart of the watchdog timer.

tWI,tr ≤ tWD,TO ≤ tWD,p

DLY

DWL

(1)

(2), (5)

(3)

(4)

WI,tr

WD,TO

Figure 36

Regardless of the status of the watchdog timer, the capacitance of CDLY could be discharged by the detector

operation. Even if watchdog timer detects a trigger of signal input to the WI pin, the WO pin outputs "L" when VDLY

reaches VDWL. After that, the watchdog timer restarts the monitoring operation if the WO pin outputs "H" when VDLY

reaches VDU.

3. 2 Autonomous watchdog operation function (Output current detection circuit)

Since the S-19500/19501 Series has a built-in output current detection circuit, the watchdog timer operates

autonomously. When using the autonomous watchdog operation function, the current flows in the load is detected

by the output current of the regulator, the watchdog timer initiates the activation when the output current is the

watchdog activation threshold current (IO,WDact) or more, the watchdog timer is deactivated when the output current

is the watchdog deactivation threshold current (IO,WDdeact) or less.

Table 17 shows the connection of WADJ pin depending on the usage of the watchdog timer.

In the S-19500 Series, the watchdog timer is deactivated regardless of the connection of the WADJ pin if the

watchdog timer is set to Disable by the WEN pin.

Table 17

Usage of Watchdog Timer Connection of WADJ Pin Status of WADJ Pin

Watchdog timer is not in use Connect to the VSS pin "L"

Watchdog timer is always activated Connect to the VOUT pin via a 270 kΩ

(recommended) resistor*1 "H"

Watchdog timer turns on and off

autonomously depending on the load current

(Autonomous watchdog operation function)

Open or connect to the VSS pin via an

external resistor*2

"H": IOUT > IO,WDact

"L": IOUT < IO,WDdeact

*1. Even if the WADJ pin is directly connected to the VOUT pin, the watchdog timer is always activated. Note that the

current consumption will increase by as many resistors as unconnected.

*2. Refer to "3. Watchdog activation threshold current adjustment resistor (RWADJ,ext)" in " Selection of

External Parts" for details.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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Depending on the output current (IOUT) of the regulator, the watchdog timer monitoring activation is as follows.

(1) When IOUT of the regulator is the watchdog activation threshold current (IO,WDact) or more, the WADJ pin voltage

(VWADJ) is higher than the reference voltage (Vref), and the output of the comparator (C1) is "H". At this time, the

watchdog timer initiates the monitoring activation.

(2) When IOUT decreases to the watchdog deactivation threshold current (IO,WDdeact) (point A in Figure 38) or less,

WADJ decreases to Vref or less and the output of C1 is "L". At this time, the watchdog timer deactivates the

monitoring. Even if IOUT increases, the watchdog timer continues the monitoring deactivation when IOUT is within

less than IO,WDact

(3) If IOUT further increases to IO,WDact (point B in Figure 38) or more, VWADJ increases to Vref or higher and the

output of C1 is "H". And then, the watchdog timer initiates the monitoring activation.

Reference voltage

circuit

VIN

VSS

WADJ

VOUT

WEN

WDT

circuit

−

WADJ,int

WADJ,ext

ref

WADJ

Reference

voltage

circuit

Figure 37 Operation of Output Current Detection Circuit

Watchdog activation

hysteresis current

O,WDhys

)

OUT

0 mA

(1) (2) (3)

Watchdog activation threshold current (I

O,WDact

)

WDT

monitoring

activation

Watchdog deactivation threshold current (I

O,WDdeact

)

WDT

monitoring

activation

WDT

monitoring

deactivation

Figure 38 Autonomous Watchdog Operation Function

Caution Due to detecting IOUT of the regulator, current flows through the resistors connected to the WADJ pin

(RWADJ,ext and RWADJ,int). Therefore, the WADJ pin voltage (VWADJ) may fluctuate since the current

flowing through RWADJ,ext and RWADJ,int also changes in the same way if the output current changes

transiently. VWADJ at that time should be evaluated with the actual device.

Remark IO,WDact, IO,WDdeact and IO,WDhys can be adjusted by connecting RWADJ,ext to the WADJ pin. Refer to

"3. Watchdog activation threshold current adjustment resistor (RWADJ,ext)" in " Selection of External

Parts" for the detail.

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3. 3 Watchdog enable circuit (only S-19500 Series)

When inputting "L" to the WEN pin, the watchdog timer becomes Disable and stops the output current detection

operation and monitoring activation. When inputting "H" to the WEN pin, the watchdog timer becomes Enable.

The watchdog timer monitoring activation is performed depending on the connection of the WADJ pin.

The WEN pin is pulled down internally by the constant current source. For this reason, the WEN pin is set to "L"

when using the WEN pin in the floating status, and the watchdog timer becomes Disable. However, in order that

the watchdog timer become Disable certainly, connect the WEN pin to GND so that "L" is input to the WEN pin

certainly, since the impedance of the WEN pin becomes high when using the WEN pin in the floating status.

In order to fix the watchdog timer to Enable, connect the WEN pin to the VOUT pin so that "H" is input to the WEN

pin.

Table 18 and Table 19 show the relation between each pin status and the watchdog timer.

3. 4 Watchdog input circuit

By inputting a rising edge to the WI pin, the watchdog timer detects a trigger. The S-19500/19501 Series has a

built-in watchdog input circuit which contains a band pass filter in the WI pin, and detects a rising edge which

satisfies an input condition as a trigger signal. Refer to *2 of Table 10 and Figure 4 in " Recommended

Operation Conditions".

During the operation of the watchdog timer, a trigger is detected only when the DLY pin voltage is in VDU to VDWL

and while the discharge operation of CDLY is being performed. Refer to "3. Watchdog timer block" in

" Operation" for details. The signal input from a monitored object by the watchdog timer to the watchdog timer

should be input with a time interval which is sufficiently shorter than the watchdog trigger time (tWI,tr).

Table 18 and Table 19 show the relation between each pin status and the watchdog timer.

Caution Under a noisy environment, the watchdog input circuit may detect the noise as a trigger signal.

Sufficiently evaluate with the actual application to confirm that a trigger is detected only in the

intended signal.

3. 5 Watchdog output circuit

Since the WO pin has a built-in resistor to pull up to the VOUT pin internally, the WO pin can output a signal

without an external pull-up resistor

Do not connect to the pin other than VOUT pin when connecting an external pull-up resistor.

In the S-19500 Series, the reset output pin and the watchdog output pin are prepared as the WO / RO pin.

The output level of the WO / RO pin is applied by the AND logic of the reset output pin and the watchdog output

pin.

Example: When the WO pin is "L" and the RO pin is "H", the WO / RO pin is "L".

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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3. 6 Each pin status and output logic

Table 18 and Table 19 show each pin status and output logic in truth table.

3. 6. 1 S-19500 Series (Product with WEN pin)

Table 18

Status

Each Pin Status Output Logic

WEN Input WADJ

Status*1 WI Input VOUT Output WO / RO

Output

WDT monitoring activation "H" "H" Trigger ≥ +VDET "H"

WDT abnormal detection "H" "H" No trigger ≥ +VDET "L"

WDT monitoring deactivation "H" "L" Don't care ≥ +VDET "H"

WDT Disable "L" Don't care Don't care ≥ +VDET "H"

Low voltage detection Don't care Don't care Don't care ≤ −VDET "L"

*1. Refer to Table 17 for the status of WADJ pin.

3. 6. 2 S-19501 Series (Product without WEN pin)

Table 19

Status

Each Pin Status Output Logic

WADJ

Status*1 WI Input VOUT Output WO Output RO Output

WDT monitoring activation "H" Trigger ≥ +VDET "H" "H"

WDT abnormal detection "H" No trigger ≥ +VDET "L" "H"

WDT monitoring deactivation "L" Don't care ≥ +VDET "H" "H"

Low voltage detection "H" Don't care ≤ −VDET "L" "L"

"L" Don't care ≤ −VDET "H" "L"

*1. Refer to Table 17 for the status of WADJ pin.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

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 Timing Charts

1. S-19500 Series (Product with WEN pin)

DWL

OUT

WADJ

WEN

DLY

WO / RO

DET

1/f

WI,tr

WD,L

WD,p

Figure 39 Example of Watchdog Timer Monitoring Operation 1

DWL

OUT

WADJ

WEN

DLY

WO / RO

DET

1/f

WI,tr

WD,L

WD,p

Figure 40 Example of Watchdog Timer Monitoring Operation 2

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

−VDET

+VDET

VIN

VOUT

VWADJ

VWEN

VWI

VDLY

VWO / RO

trd trr

≪trr

VDU

VDRL

Figure 41 Example of Detector Operation

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

2. S-19501 Series (Product without WEN pin)

VIN

VOUT

VWADJ

VWI

VDLY

VRO

VWO

trd

1/fWI

tWI

tWD,L

tWD,p

VDU

VDWL

+VDET

Figure 42 Example of Watchdog Timer Monitoring Operation

−VDET

+VDET

VIN

VOUT

VWADJ

VWI

VDLY

VRO

VWO

trd trr

≪trr

VDU

VDRL

Figure 43 Example of Detector Operation

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 Precautions

• Wiring patterns for the VIN pin, the VOUT pin and GND should be designed so that the impedance is low. When

mounting an output capacitor between the VOUT pin and the VSS pin (CL) and an input capacitor between the VIN

pin and the VSS pin (CIN), the distance from the capacitors to these pins should be as short as possible.

• Note that generally the output voltage may increase when a series regulator is used at low load current (0.1 mA or

less).

• Note that generally the output voltage may increase due to the leakage current from an output transistor when a

series regulator is used at high temperature.

• Generally a series regulator may cause oscillation, depending on the selection of external parts. The following

conditions are recommended for the S-19500/19501 Series. However, be sure to perform sufficient evaluation under

the actual usage conditions for selection, including evaluation of temperature characteristics. Refer to "4. Example

of equivalent series resistance vs. Output current characteristics (Ta = −40°C to +125°C)" in " Reference

Data" for the equivalent series resistance (RESR) of the output capacitor.

Input capacitor (CIN): 2.2 μF or more

Output capacitor (CL): 2.2 μF or more

• In a series regulator, generally the values of overshoot and undershoot in the output voltage vary depending on the

variation factors of power-on, power supply fluctuation and load fluctuation, or output capacitance.

Determine the conditions of the output capacitor after sufficiently evaluating the temperature characteristics of

overshoot or undershoot in the output voltage with the actual device.

• The voltage regulator may oscillate when the impedance of the power supply is high and the input capacitance is

small or an input capacitor is not connected.

• Overshoot may occur in the output voltage momentarily if the voltage is rapidly raised at power-on or when the

power supply fluctuates. Sufficiently evaluate the output voltage at that time with the actual device.

• If the VOUT pin is steeply shorted with GND, a negative voltage exceeding the absolute maximum ratings may occur

to the VOUT pin due to resonance of the wiring inductance and the output capacitance in the application. The

negative voltage can be limited by inserting a protection diode between the VOUT pin and the VSS pin or inserting a

series resistor to the output capacitor.

• The application conditions for the input voltage, the output voltage, and the load current should not exceed the power

dissipation.

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

protection circuit.

• In determining the output current, attention should be paid to the output current value specified in Table 11 in

" Electrical Characteristics" and footnote *7 of the table.

• 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.

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

 Characteristics (Typical Data)

1. Regulator block

1. 1 Output voltage vs. Output current (When load current increases) (Ta = +25°C)

1. 1. 1

OUT = 3.3

1. 1. 2

OUT = 5.0 V

4.0

0.0

0 600

OUT

[mA]

3.0

2.0

1.0

OUT

[V]

500400300200100

= 3.8 V

= 4.3 V

= 13.5 V

6.0

0.0

0 600

OUT

[mA]

OUT

[V]

500400300200100

5.0

4.0

3.0

2.0

1.0

= 5.5 V

= 6.0 V

= 13.5 V

1. 2 Output voltage vs. Input voltage (Ta = +25°C)

1. 2. 1 VOUT = 3.3 V 1. 2. 2 VOUT = 5.0 V

4.0

0.0

018

[V]

3.0

2.0

1.0

OUT

[V]

1512963

OUT

= 1 mA

OUT

= 30 mA

OUT

= 10 mA

OUT

= 100 mA

6.0

0.0

018

[V]

OUT

[V]

1512963

5.0

4.0

3.0

2.0

1.0

OUT

= 1 mA

OUT

= 30 mA

OUT

= 10 mA

OUT

= 100 mA

1. 3 Dropout voltage vs. Output current

1. 3. 1 VOUT = 3.3 V 1. 3. 2 VOUT = 5.0 V

200

0 200

OUT

[mA]

150

100

drop

[mV]

15010050

125

°C

150

°C

−

°C

200

0 200

OUT

[mA]

150

100

drop

[mV]

15010050

125

°C

150

°C

−

°C

1. 4 Dropout voltage vs. Junction temperature

1. 4. 1 VOUT = 3.3 V 1. 4. 2 VOUT = 5.0 V

−25 0 150125100755025−40

[°C]

100

drop

[mV]

OUT

= 30 mA

OUT

= 100 mA

−25 0 150125100755025−40

[°C]

100

drop

[mV]

OUT

= 30 mA

OUT

= 100 mA

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

1. 5 Output voltage vs. Junction temperature

1. 5. 1 VOUT = 3.3 V

VIN = 13.5 V

1. 5. 2 VOUT = 5.0 V

VIN = 13.5 V

−25 0 150125100755025−40

[°C]

3.0

3.6

OUT

[V]

3.5

3.4

3.3

3.2

3.1

−25 0 150125100755025−40

[°C]

4.7

5.3

OUT

[V]

5.2

5.1

5.0

4.9

4.8

1. 6 Ripple rejection (Ta = +25°C)

1. 6. 1 VOUT = 3.3 V

VIN = 13.5 V, CL = 2.2 μF

1. 6. 2 VOUT = 5.0 V

VIN = 13.5 V, CL = 2.2 μF

100 1k 10k

Ripple Rejection [dB]

Frequency [Hz]

10 1M

100

100k

OUT

= 1 mA

OUT

= 30 mA

OUT

= 100 mA

100 1k 10k

Ripple Rejection [dB]

Frequency [Hz]

10 1M

100

100k

OUT

= 1 mA

OUT

= 30 mA

OUT

= 100 mA

2. Detector block

2. 1 Detection voltage, Release voltage vs. Junction temperature

2. 1. 1 −

DET = 2.6

2. 1. 2 −

DET = 4.7

−25 0 150125100755025−40

[°C]

2.2

3.2

3.0

2.8

2.6

2.4

−V

DET

,+V

DET

[V]

DET

−V

DET

−25 0 150125100755025−40

[°C]

4.3

5.3

5.1

4.9

4.7

4.5

−V

DET

,+V

DET

[V]

DET

−V

DET

2. 2 Hysteresis width vs. Junction temperature

2. 2. 1 −

DET = 2.6

2. 2. 2 −

DET = 4.7

−25 0 150125100755025−40

[°C]

300

HYS

[mV]

250

200

150

100

−25 0 150125100755025−40

[°C]

300

HYS

[mV]

250

200

150

100

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

2. 3 Reset output current vs. VDS

2. 3. 1 −

DET = 2.6

2. 3. 2 −

DET = 4.7

100

0.0 3.0

IRO [mA]

VDS [V]

2.52.01.51.00.5

Ta =

125

°C

Ta =

°C

Ta =

−

°C

200

[mA]

[V]

160

120

4321

Ta =

125

°C

Ta =

°C

Ta =

−

°C

2. 4 Reset output current vs. Output voltage

2. 4. 1 −VDET = 2.6 V

VDS = 0.4 V

2. 4. 2 −VDET = 4.7 V

VDS = 0.4 V

0.0 3.0

IRO [mA]

VOUT [V]

2.52.01.51.00.5

Ta =

125

°C

Ta =

°C

Ta =

−

°C

[mA]

OUT

[V]

4321

Ta =

125

°C

Ta =

°C

Ta =

−

°C

2. 5 RO pin voltage vs. Output voltage

2. 5. 1 −VDET = 2.6 V

VDS = 0.4 V

2. 5. 2 −VDET = 4.7 V

VDS = 0.4 V

0.0 3.0

[V]

OUT

[V]

2.52.01.51.00.5

Tj =

125

°C

Tj =

150

°C

Tj =

°C

Tj =

−

°C

[V]

OUT

[V]

4321

125

°C

150

°C

−

°C

Remark IRO: Nch transistor output current

RO: Nch transistor output voltage

DS: Drain-to-source voltage of Nch transistor

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

2. 6 Release delay time vs. Junction temperature

2. 6. 1 −

DET = 2.6

2. 6. 2 −

DET = 4.7

−25 0 150125100755025−40

[°C]

[ms]

−25 0 150125100755025−40

[°C]

[ms]

2. 7 Release delay time vs. Release delay time and monitoring time adjustment capacitance

2. 7. 1 −

DET = 2.6

2. 7. 2 −

DET = 4.7

1000

100

0.1

100101

[ms]

DLY

[nF]

125

°C

150

°C

−

°C

1000

100

0.1

100101

[ms]

DLY

[nF]

125

°C

150

°C

−

°C

2. 8 Reset reaction time vs. Junction temperature

2. 8. 1 −

DET = 2.6

2. 8. 2 −

DET = 4.7

−25 0 150125100755025−40

[°C]

[μs]

−25 0 150125100755025−40

[°C]

[μs]

2. 9 Reset reaction time vs. Release delay time and monitoring time adjustment capacitance

2. 9. 1 −

DET = 2.6

2. 9. 2 −

DET = 4.7

100

1000

100101

[μs]

DLY

[nF]

Tj =

125

°C

Tj =

150

°C

Tj =

°C

Tj =

−

°C

100

1000

100101

[μs]

DLY

[nF]

Tj =

125

°C

Tj =

150

°C

Tj =

°C

Tj =

−

°C

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

3. Watchdog timer block

3. 1 Watchdog trigger time vs. Junction temperature

3. 1. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 1. 2 VOUT = 5.0 V

VIN = 13.5 V

−25 0 150125100755025−40

[°C]

WI,tr

[ms]

−25 0 150125100755025−40

[°C]

WI,tr

[ms]

3. 2 Watchdog trigger time vs. Release delay time and monitoring time adjustment capacitance

3. 2. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 2. 2 VOUT = 5.0 V

VIN = 13.5 V

1000100101

WI,tr

[ms]

DLY

[nF]

10000

1000

100

0.1

+ °C

− °C

1000100101

WI,tr

[ms]

DLY

[nF]

10000

1000

100

0.1

+ °C

− °C

3. 3 Charge current, discharge current vs. Junction temperature

3. 3. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 3. 2 VOUT = 5.0 V

VIN = 13.5 V

−25 0 150125100755025−40

[°C]

D,cha

, I

D,dcha

[

D,dcha

D,cha

−25 0 150125100755025−40

[°C]

D,cha

D,dcha

[

D,dcha

D,cha

3. 4 Upper timing threshold voltage, lower watchdog timing threshold voltage, lower reset timing threshold voltage vs. Junction temperature

3. 4. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 4. 2 VOUT = 5.0 V

VIN = 13.5 V

−25 0 150125100755025−40

[°C]

0.0

2.5

, V

DWL

, V

DRL

[V]

2.0

1.5

1.0

0.5

DWL

DRL

−25 0 150125100755025−40

[°C]

0.0

2.5

2.0

1.5

1.0

0.5

, V

DWL

, V

DRL

[V]

DWL

DRL

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

3. 5 Watchdog activation threshold current, watchdog deactivation threshold

current vs. Junction temperature

3. 5. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 5. 2 VOUT = 5.0 V

VIN = 13.5 V

−25 0 150125100755025−40

[°C]

0.0

3.0

O,WDact

, I

O,WDdeact

[mA]

2.5

2.0

1.5

1.0

0.5 I

O,WDdeact

O,WDact

−25 0 150125100755025−40

[°C]

0.0

3.0

O,WDact

, I

O,WDdeact

[mA]

2.5

2.0

1.5

1.0

0.5 I

O,WDdeact

O,WDact

3. 6 Watchdog activation

threshold

current, Watchdog deactivation

threshold

current

vs. Watchdog activation threshold current adjustment resistance (Ta = +25°C)

3. 6. 1 VOUT = 3.3 V

VIN = 13.5 V

3. 6. 2 VOUT = 5.0 V

VIN = 13.5 V

100

10000

100010010

O,WDact

, I

O,WDdeact

[mA]

WADJ,ext

[kΩ]

O,WDdeact

O,WDact

100

10000

100010010

O,WDact

O,WDdeact

[mA]

WADJ,ext

[kΩ]

O,WDdeact

O,WDact

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

4. Overall

4. 1 Current consumption during operation vs. Input voltage

4. 1. 1 VOUT = 3.3 V, −VDET = 2.6 V

When watchdog timer is deactivated

4. 1. 2 VOUT = 5.0 V, −VDET = 4.7 V

When watchdog time

is deactivated

300

018

SS1

[μA]

[V]

15963

250

200

150

100

+ °C

− °C

300

SS1

[μA]

[V]

250

200

150

100

0181596312

+ °C

− °C

4. 2 Current consumption during operation vs. Output current

4. 2. 1 VOUT = 3.3 V, −VDET = 2.6 V

VIN = 13.5 V, WADJ pin is open

4. 2. 2 VOUT = 5.0 V, −VDET = 4.7 V

VIN = 13.5 V, WADJ pin is open

160

0 200

SS1

[μA]

OUT

[mA]

1601208040

120

Ta =

125

°C

Ta =

−

°C

Ta =

°C

160

0 200

SS1

[μA]

OUT

[mA]

1601208040

120

Ta =

125

°C

Ta =

−

°C

Ta =

°C

4. 3 Current consumption during operation vs. Junction temperature

4. 3. 1 VOUT = 3.3 V, −VDET = 2.6 V

VIN = 13.5 V, WADJ pin is open

4. 3. 2 VOUT = 5.0 V, −VDET = 4.7 V

VIN = 13.5 V, WADJ pin is open

160

SS1

[μA]

120

−25 0 150125100755025−40

[°C]

OUT

= 50 mA

OUT

= 5 mA

OUT

= 200 mA

160

SS1

[μA]

120

−25 0 150125100755025−40

[°C]

OUT

= 50 mA

OUT

= 5 mA

OUT

= 200 mA

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

Rev.1.7_00 S-19500/19501 Series

 Reference Data

1. Characteristics of input transient response (Ta = +25°C)

1. 1 VOUT = 3.3 V

OUT

= 30 mA, C

= 2.2

F, V

= 11.5 V

↔

13.5 V, t

= t

= 5.0

1. 2 VOUT = 5.0 V

OUT

= 30 mA, C

= 2.2

F, V

= 11.5 V

↔

13.5 V, t

= t

= 5.0

3.8

3.2

−100 500

OUT

[V]

4003002001000

3.7

3.6

3.5

3.4

3.3

t [μs]

[V]

OUT

6.0

4.8

−100 500

OUT

[V]

4003002001000

5.8

5.6

5.4

5.2

5.0

t [μs]

[V]

OUT

2. Characteristics of load transient response (Ta = +25°C)

2. 1 VOUT = 3.3 V

VIN = 13.5 V, CL = 2.2 μF, IOUT = 50 mA ↔ 100 mA

2. 2 VOUT = 5.0 V

VIN = 13.5 V, CL = 2.2 μF, IOUT = 50 mA ↔ 100 mA

3.7

3.1

−100 500

OUT

[V]

4003002001000

3.6

3.5

3.4

3.3

3.2

t [μs]

150

−150

100

−50

−100

OUT

[mA]

OUT

5.8

4.6

−100 500

VOUT [V]

4003002001000

5.6

5.4

5.2

5.0

4.8

t [μs]

150

−150

100

−50

−100

IOUT [mA]

VOUT

IOUT

3. Load dump characteristics (Ta = +25°C)

3. 1 VOUT = 5.0 V

OUT

= 0.1 mA, V

= 13.5 V

↔

45.0 V, C

= C

= 2.2

6.0

4.8

−0.1 0.9

VOUT [V]

0.40.30.20.10

5.8

5.6

5.4

5.2

5.0

t [s]

−10

VIN [V]

0.5 0.6 0.7 0.8

VOUT

VIN

4. Example of equivalent series resistance vs. Output current characteristics (Ta =

−

40°C to

125°C)

CIN = CL = 2.2 μF, CDLY = 47 nF

0.1 200

OUT

[mA]

ESR

[Ω]

Stable

CIN

VIN

VSS

CL*1

RESR

S-19500

Series

VOUT

WO / RO

WEN

DLY

CDLY

WADJ

*1. CL: Murata Manufacturing Co., Ltd.

GCM31CR71H225K (2.2 μF)

Figure 44 Figure 45

AUTOMOTIVE, 125°C OPERATION, 36 V INPUT, 200 mA, BUILT-IN WATCHDOG TIMER VOLTAGE REGULATOR WITH RESET FUNCTION

S-19500/19501 Series Rev.1.7_00

 Power Dissipation

0 25 50 75 100 125 150 175

Ambient temperature (Ta) [°C]

Power dissipation (P

) [W]

= +150°C max.

HSOP-8A

Board Power Dissipation (PD)

A 1.20 W

B 1.69 W

C 3.21 W

D 3.38 W

E 4.03 W

(1)

(2)

(3)

Board A

Board B

Board C

Thermal via Number: 4

Diameter: 0.3 mm

Number of copper foil layer 4

Copper foil layer [mm]

Land pattern and wiring for testing: t0.070

74.2 x 74.2 x t0.035

74.2 x 74.2 x t0.070

Material FR-4

Thermal via -

Item Specification

Copper foil layer [mm]

Land pattern and wiring for testing: t0.070

74.2 x 74.2 x t0.035

74.2 x 74.2 x t0.070

Size [mm] 114.3 x 76.2 x t1.6

Material FR-4

Number of copper foil layer 4

Copper foil layer [mm]

Land pattern and wiring for testing: t0.070

Item Specification

74.2 x 74.2 x t0.070

Size [mm] 114.3 x 76.2 x t1.6

Item Specification

Thermal via -

Material FR-4

Number of copper foil layer 2

ICMountArea

enlargedview

HSOP-8A Test Board

No. HSOP8A-A-Board-SD-1.0

ABLIC Inc.

(4)

(5)

Size [mm] 114.3 x 76.2 x t1.6

Material FR-4

Item Specification

Number of copper foil layer 4

Copper foil layer [mm]

Pattern for heat radiation: 2000mm2 t0.070

74.2 x 74.2 x t0.035

74.2 x 74.2 x t0.070

Size [mm] 114.3 x 76.2 x t1.6

Material FR-4

Thermal via -

Item Specification

Board D

Board E

Thermal via Number: 4

Diameter: 0.3 mm

Number of copper foil layer 4

Copper foil layer [mm]

Pattern for heat radiation: 2000mm

t0.070

74.2 x 74.2 x t0.035

enlargedview

ICMountArea

HSOP-8A Test Board

No. HSOP8A-A-Board-SD-1.0

ABLIC Inc.

No.

TITLE

UNIT

ANGLE

No. FH008-A-P-SD-2.0

HSOP8A-A-PKG Dimensions

FH008-A-P-SD-2.0

0.4±0.05

1.27

5.02±0.2

85 58

3.0

0.20±0.05

ABLIC Inc.

No.

TITLE

UNIT

ANGLE

ø2.0±0.05

ø1.5 0.3±0.05

2.1±0.1

8.0±0.1

6.7±0.1

2.0±0.05

Feed direction

4.0±0.1(10 pitches:40.0±0.2)

HSOP8A-A-Carrier Tape

No. FH008-A-C-SD-1.0

FH008-A-C-SD-1.0

+0.1

-0.0

ABLIC Inc.

No.

TITLE

UNIT

ANGLE

QTY. 4,000

HSOP8A-A-Reel

No. FH008-A-R-SD-1.0

FH008-A-R-SD-1.0

2±0.5

ø13±0.2

ø21±0.8

Enlarged drawing in the central part

17.4±1.0

13.4±1.0

ABLIC Inc.

No.

TITLE

UNIT

ANGLE

HSOP8A-A

-Land Recommendation

FH008-A-L-SD-1.0

1.27

0.76

1.27 1.27

3.2

No. FH008-A-L-SD-1.0

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.

6. When exporting the products, comply with the Foreign Exchange and Foreign Trade Act and all other export-related

laws, and follow the required procedures.

7. The products are strictly prohibited from using, providing or exporting for the purposes of the development of

weapons of mass destruction or military use. ABLIC Inc. is not liable for any losses, damages, claims or demands

caused by any provision or export to the person or entity who intends to develop, manufacture, use or store nuclear,

biological or chemical weapons or missiles, or use any other military purposes.

8. The products are not designed to be used as part of any device or equipment that may affect the human body, human

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

systems, infrastructure control systems, vehicle equipment, traffic systems, in-vehicle equipment, aviation equipment,

aerospace equipment, and nuclear-related equipment), excluding when specified for in-vehicle use or other uses by

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

ABLIC Inc. is not liable for any losses, damages, claims or demands caused by unauthorized or unspecified use of

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

damage, etc. that may ensue from the products' failure or malfunction.

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

allowed to apply for the system on customer's own responsibility.

10. The products are not designed to be radiation-proof. The necessary radiation measures should be taken in the

product design by the customer depending on the intended use.

11. The products do not affect human health under normal use. However, they contain chemical substances and heavy

metals and should therefore not be put in the mouth. The fracture surfaces of wafers and chips may be sharp. Be

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

12. When disposing of the products, comply with the laws and ordinances of the country or region where they are used.

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

ABLIC Inc. or a third party. Reproduction or copying of the information from this document or any part of this

document described herein for the purpose of disclosing it to a third-party is strictly prohibited without the express

permission of ABLIC Inc.

14. For more details on the information described herein or any other questions, please contact ABLIC Inc.'s sales

representative.

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.

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