SC802SEN - Exar Corporation

SP690T/S/R, SP802T/S/R,

SP804T/S/R, and SP805T/S/R

3.0V/3.3V Low Power Microprocessor

Supervisory with Battery Switch-Over

The SP690T/S/R, SP802T/S/R, SP804T/S/R and SP805T/S/R devices are a family of

microprocessor (µP) supervisory circuits that integrate a myriad of components involved in

discrete solutions to monitor power-supply and battery-control functions in µP and digital

systems. The series will significantly improve system reliability and operational efficiency

when compared to discrete solutions. The features of the SP690T/S/R, SP802T/S/R,

SP804T/S/R and SP805T/S/R devices include a watchdog timer, a µP reset and backup-

battery switchover, and power-failure warning; a complete µP monitoring and watchdog

solution. The series is ideal for 3.0V or 3.3V applications in portable electronics, computers,

controllers, and intelligent instruments and is a solid match for designs where it is critical to

monitor the power supply to the µP and it’s related digital components. Refer to Sipex's

SP690A/692A/802L/802M/805L/805M series for similar devices designed for +5V systems.

■ RESET and RESET Outputs

■ Reset asserted down to VCC = 1V

■ Reset Time Delay - 200ms

■ Watchdog Timer - 1.6 sec timeout

■ 40µA Maximum VCC Supply Current

■ 1µA Maximum Battery Supply Current

■ Power Switching

50mA Output in VCC Mode (1.5Ω)

10mA Output in Battery Mode (15Ω)

■ Battery Can Exceed VCC in Normal Operation

■ Precision Voltage Monitor for Power-Fail

or Low-Battery Warning

■ Available in 8 pin SO and DIP packages

■ Pin Compatible Upgrades to

MAX690T/S/R, MAX802T/S/R,

MAX804T/S/R, MAX805T/S/R

DESCRIPTION

r e b m u N t r a P T E S E R e v i t c A evitcAevitcAevitcAevitcA T E S E R d l o h s e r h T dlohserhTdlohserhTdlohserhTdlohserhT T E S E R y c a r u c c A ycaruccAycaruccAycaruccAycaruccA I F P y c a r u c c A ycaruccAycaruccAycaruccAycaruccA g o d h c t a W t u p n I tupnItupnItupnItupnI y r e t t a B -p u k c a B h c t i w S hctiwShctiwShctiwShctiwS

T 5 0 8 /T 0 9 6 P S H G I H /W O L V 5 7 0 .3 V m 5 7 ± %4 ± SE Y SE Y

T 4 0 8 /T 2 0 8 P S H G I H /W O L V 5 7 0 .3 V m 0 6 ± %2 ± SE Y SE Y

S 5 0 8 /S 0 9 6 P S H G I H /W O L V 5 2 9 .2 V m 5 7 ± %4 ± SE Y SE Y

S 4 0 8 /S 2 0 8 P S H G I H /W O L V 5 2 9 .2 V m 0 6 ± %2 ± SE Y SE Y

R 5 0 8 /R 0 9 6 P S H G I H /W O L V 5 2 6 .2 V m 5 7 ± %4 ± SE Y SE Y

R 4 0 8 /R 2 0 8 P S H G I H /W O L V 5 2 6 .2 V m 0 6 ± %2 ± SE Y SE Y

ABSOLUTE MAXIMUM RATINGS

These are stress ratings only and functional operation of the device at

these ratings or any other above those indicated in the operation

sections of the specifications below is not implied. Exposure to absolute

maximum rating conditions for extended periods of time may affect

reliability and cause permanent damage to the device.

VCC..................................................................................-0.3V to 6.0V

VBATT................................................................................-0.3V to 6.0V

All Other Inputs (NOTE 1).................................-0.3V to the higher of VCC or VBATT

Continuous Input Current:

VCC..................................................................................100mA

VBATT..................................................................................20mA

GND..................................................................................20mA

WDI, PFI...........................................................................20mA

Continuous Output Current:

RES ET, R ESET, PF O... .... ....... .... .......................................20mA

VOUT......................................................................................100mA

Power Dissipation per Package:

8pi n N S O I C ( d e r ate 6 . 1 4 m W /°C above +70°C)..............500mW

8pi n P D I P ( d e r a te 11 . 8 m W / °C above +70°C)..............1,000mW

Sto r a g e T e m p e r a t u r e . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-65°C to +160°C

Lead Temperature(soldering,10sec).............................................+300°C

ESD Rating........................................................4KV Human Body Model

SPECIFICATIONS

VCC = 3.17V to 5.50V for the SP690T/SP80_T, VCC = 3.02V to 5.50V for the SP690S/SP80_S, VCC = 2.72V to 5.50V for the SP690R/SP80_R, VBATT = 3.60V, and

TA = TMIN to TMAX unless otherwise noted. Typical values taken at TAMB = +25OC.

S R E T E M A R A P .N I M .P Y T .X A M ST I N U SN O I T I D N O C

, e g n a R e g a t l o V g n i t a r e p O 0 . 1 5 . 5 s t l o V

V r o

YR E T T A B

, ET O N 1

I , t n e r r u C y l p p u S

YL P P U S

5 2 04 µA I g n i d u l c x e

TU O

C C

y r e t t a B n i t n e r r u C y l p p u S e d o M p u k c a B 0 2 04 µA V

V , V 0 . 2 =

YR E T T A B

,V 3 . 2 =

I g n i d u l c x e

TU O

YR E T T A B

n i t n e r r u C y l p p u S, e d o M y n A ET O N 2 4 . 0 1 µA I g n i d u l c x e

TU O

YR E T T A B

E T O N , t n e r r u C e g a k a e L 3 1 0 0 . 0 5. 0 µA

YR E T T A B

E T O N , t n e r r u C e g a k a e L 4 1. 0 - 2 0 . 0 µA V >V 3 .3

C C

Y R E T T A B

V2 . 0 +

V , e g a t l o V t u p t u O

TU O

30 . 0 -

3. 0 -

51 0 0 . 0 -

57 0 0 . 0 -

57 0 . 0 -

30 0 0 . 0 - VA m 5 =I

TU O

A m 0 5 =

TU O

05 2 = µ V, A

V5 . 2 >

TU O

e d o M p u k c a B -y r e t t a B n i V

YR E T T A B

20 . 0 - V

YR E T T A B

54 0 0 . 0 -

YR E T T A B

81 0 . 0 -

YR E T T A B

51 . 0 -

V I

T U O

V, A µ 0 5 2 =

YR E T T A B

V3 . 2 =

TU O

V, A m 1 =

YR E T T A B

V3 . 2 =

TU O

BV , A m 0 1 =

YR E T T A

V3 . 3 =

, d l o h s e r h T h c t i w S y r e t t a B

g n i l l a f 5 6 0 . 0 0 3 . 2 5 2 0 . 0 0 4 . 2 05 .2 VV

YR E T T A B

V-

C C

5E T O N , V 5 7 . 1 >

YR E T T A B

6E T O N ,

, d l o h s e r h T h c t i w S y r e t t a B

7E T O N , g n i s i r Vt e s e R e h t o t l a c i t n e d i e r a s e u l a V V t a s e u l a v d l o h s e r h T

g n i s i r

S R E T E M A R A P .N I M .P Y T .X A M ST I N U SN O I T I D N O C

V , d l o h s e r h T t e s e R

TS R

8 E T O N

0 0 . 3 0 0 . 3 5 8 . 2 5 8 . 2 5 5 . 2 5 5 . 2

5 7 0 . 3 5 8 0 . 3 5 2 9 . 2 5 3 9 . 2 5 2 6 . 2 5 3 6 . 2

5 1 . 3 7 1 . 3 0 0 . 3 2 0 . 3 0 7 . 2 2 7 . 2

V , T 5 0 8 /T 0 9 6 P S

g n i l l a f

V , T 5 0 8 /T 0 9 6 P S

g n i s i r

V , S 5 0 8 /S 0 9 6 P S

g n i l l a f

V , S 5 0 8 /S 0 9 6 P S

g n i s i r

V , R 5 0 8 /R 0 9 6 P S

g n i l l a f

V , R 5 0 8 /R 0 9 6 P S

g n i s i r

0 0 . 3 0 0 . 3 8 8 . 2 8 8 . 2 9 5 . 2 9 5 . 2

5 7 0 . 3 5 8 0 . 3 5 2 9 . 2 5 3 9 . 2 5 2 6 . 2 5 3 6 . 2

2 1 . 3 4 1 . 3 0 0 . 3 2 0 . 3 0 7 . 2 2 7 . 2

V , T 4 0 8 /T 2 0 8 P S

g n i l l a f

V , T 4 0 8 /T 2 0 8 P S

g n i s i r

V , S 4 0 8 /S 2 0 8 P S

g n i l l a f

V , S 4 0 8 /S 2 0 8 P S

g n i s i r

V , R 4 0 8 /R 2 0 8 P S

g n i l l a f

V , R 4 0 8 /R 2 0 8 P S

g n i s i r

t e s e R t, d o i r e P t u o e m i T

04 1 00 2 08 2 s m

V , e g a t l o V t u p t u O O F P , T E S E R

H O

3 . 0 - V

5 1 . 0 - V I

EC R U O S

Aµ 0 3 =

V , e g a t l o V t u p t u O O F P , T E S E R

L O

60 . 0 03 . 0 V I

KN I S

e r e h w _ 2 0 8 / _ 0 9 6 P S , A m 2 . 1 =

TS R

m u m i n i m

V , e g a t l o V t u p t u O O F P , T E S E R

L O

31 . 0 03 . 0 V V

YR E T T A B

V, V 0 =

I , V 0 . 1 =

KN I S

Aµ 0 4 =

V , e g a t l o V t u p t u O T E S E R

L O

6 0 . 0 03 . 0 V I

KN I S

e r e h w _ 5 0 8 / _ 4 0 8 P S , A m 2 . 1 =

TS R

m u m i x a m

, t n e r r u C e g a k a e L t u p t u O T E S E R 1 1 E T O N 1 - 1 - µA V

YR E T T A B

V, V 0 =

TS R

, m u m i n i m

TE S E R

V r o V 0 =

I , t n e r r u C D N G o t t r o h S t u p t u O

S O

T E S E R d n a O F P 0 8 1 00 5 µA V

V, V 3 . 3 =

V0 =

t , t u o e m i T g o d h c t a W

21 . 1 06 . 1 42 . 2 s V

V6 . 3 <

h t d i W e s l u P I D W 1 µs

d l o h s e r h T t u p n I I D W V

H I

V x 3 . 0

V x 7 . 0

t n e r r u C t u p n I I D W 1 - 10 . 0 1 µA V < V 0

V5 . 5 <

d l o h s e r h T t u p n I I F P 0 0 2 . 1 5 2 2 . 1 5 2 . 1 5 2 . 1 0 0 3 . 1 5 7 2 . 1 VV , _ 5 0 8 / _ 0 9 6 P S

< V , V 6 . 3

I F P

g n i l l a f

V , _ 4 0 8 / _ 2 0 8 P S

< V , V 6 . 3

I F P

g n i l l a f

t n e r r u C t u p n I I F P 5 2 - 10 . 0 52 A n

V , s i s e r e t s y H I F P

HF P

01 02 V m V, g n i s i r I F P

< V 6 . 3

SPECIFICATIONS (continued)

VCC = 3.17V to 5.50V for the SP690T/SP80_T, VCC= 3.02V to 5.50V for the SP690S/SP80_S, VCC= 2.72V to 5.50V for the SP690R/SP80_R, VBATT= 3.60V, and

TA= TMINto TMAXunless otherwise noted. Typical values taken at TAMB= +25OC.

SPECIFICATIONS (continued)

VCC = 3.17V to 5.50V for the SP690T/SP80_T, VCC = 3.02V to 5.50V for the SP690S/SP80_S, VCC = 2.72V to 5.50V for the SP690R/SP80_R, VBATT = 3.60V, and

TA = TMIN to TMAX unless otherwise noted. Typical values taken at TAMB = +25OC.

NOTE 1: The following are tested at VBATT = 3.6V and VCC = 5 . 5 V : VCC sup p l y c u r r ent, w atch dog

functionality, logic input leakage, PFI functionality, and the RESET and RESET states. The state of

RESET or RESET and PFO is tested at VCC = VCC(min).

NOTE 2: Tested VBATT = 3.6V, VCC = 3.5V and 0V.

NOTE 3: Leakage current into the battery is tested under the following worst-case conditions: VCC

= 5.5V, VBATT = 1.8V and at VCC = 1.5V, VBATT = 1.0V.

NOTE 4: "-" equals the battery-charging current, "+" equals the battery-discharging current.

NOTE 5: When VSW > VCC > VBATT, VOUT remains connected to VCC until VCC drops below VBATT. The

VCC-to-VBATT comparator has a small 25mV typical hysteresis to prevent oscillation.

NOTE 6: When VBATT > VCC > VSW, VOUT remains connected to VCC until VCC drops below the battery

switch threshold, VSW.

NOTE 7: VOUT switches from VBATT to VCC when VCC rises above the reset threshold, independent of

VBATT. Switchover back to VCC occurs at the exact voltage that causes RESET to go HIGH (on the

SP804_ and SP805_ RESET goes LOW). Switchover occurs 200ms prior to reset.

NOTE 8: The reset threshold tolerance is wider for VCC rising than for VCC falling to accommodate the

10mV typical hysteresis, which prevents internal oscillation.

NOTE 9: SP690_ and SP802_ devices only.

NOTE 10: SP804_ and SP805_ devices only.

NOTE 11: The leakage current into or out of the RESET pin is tested with RESET asserted (RESET

output high impedance).

INTERNAL BLOCK DIAGRAM

1.25V

BATTERY

SWITCHOVER

CIRCUIT

PFI

WATCHDOG

TIMER

RESET

GENERATOR

VCC

BATTERY

SWITCHOVER

COMPARATOR

RESET

COMPARATOR

1.25V

WDI

VBATT

PFO

RESET / RESET*

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

*SP804T/S/R and SP805T/S/R only

POWER-FAIL

COMPARATOR

OUT

GND 3

PIN ASSIGNMENTS

Pin 1 —V OUT — Output Supply Voltage for

CMOS RAM. When VCC is above the

reset threshold, VOUT connects to VCC

through a P-channel MOSFET switch.

When VCC falls below the VSW and

VBATTERY, VBATTERY connects to VOUT.

Connect to VCC if no battery is used.

Pin 2 — VCC — +5V S upply I nput

Pin 3 — GND — Ground reference for all

signals

Pin 4 — PFI — Power-Fail Comparator Input.

When PFI is less than 1.25V or when VCC

falls below the VSW, PFO goes LOW,

otherwise PFO remains HIGH. Connect

to GND if unused.

Pin 5 — PFO — Power-Fail Comparator

Output. Leave open if unused.

Pin 6 — WDI — Watchdog Input. If WDI

remains HIGH or LOW for 1.6 seconds,

the internal watchdog timer triggers a

reset. The internal watchdog timer clears

when reset is asserted or WDI sees a

rising or falling edge. The watchdog

function cannot be disabled.

Pin 7 for SP690_/802_ only — Active-LOW

Reset Output. — Whenever RESET is

triggered by a watchdog timeout, it goes

LOW for 200ms. It stays LOW whenever

VCC is below the reset threshold and re-

mains LOW for 200ms after VCC rises

above the reset threshold or when the

watchdog triggers a reset.

Pin 7 for SP804_/805_ only — Active-HIGH

Open-Drain Reset Output. — The

inverse operation of RESET.

Pin 8 — VBATTERY — B a ck u p- Ba t te r y I n pu t .

When VCC falls below VSW and VBATTERY,

VOUT switchesfrom VCC to VBATTERY.

When VCC rises above the reset threshold,

VOUT reconnects to VCC. VBATTERY may

exceed VCC. Connect to VCC if no battery

is used.

VOUT

VCC

GND

PFI

VBATTERY

RESET / RESET*

WDI

PFO

*SP804T/S/R and SP805T/S/R only

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

PINOUT

TYPICAL CHARACTERISTICS (TAMB = 25oC, unless otherwise noted)

Figure 1. VCC Supply Current vs. Temperature (Normal

Mode)

Figure 3. PFI Threshold vs. Temperature

Figure 2. Battery Supply Current vs. Temperature

Figure 4. VBATTERY to VOUT ON-Resistance vs. Temperature

Figure 5. VCC to VOUT On-Resistance vs. Temperature Figure 6. Reset Threshold vs. Temperature

20-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (

Supply Current (µA)

10000

1000

100

0.1

-60 -35 -10 15 40 65 90 115 140

Temperature (oC)

Battery Supply Current (nA)

1.262

1.26

1.258

1.256

1.254

1.252

1.25

1.248

-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (

PFI Threshold (Volts)

0-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (oC)

VBATTERY to VOUT On-Resistance (Ω )

3.5

2.5

1.5

0.5

-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (oC)

On Resistance (Ω )

3.15

3.13

3.11

3.09

3.07

3.05

-60 -35 -10 15 40 65 90 115 140

Temperature (

Reset Threshold (Volts)

Figure 7. Reset Output Resistance vs. Temperature

Figure 9. Battery Current vs. VCC Voltage

Figure 8. Reset Timeout vs. Temperature

Figure 10. Reset-Comparator Propagation Delay vs.

Temperature

Figure 11. VCC to VOUT Vs. Output Current Figure 12. VBATTERY to VOUT Vs. Output Current

1E-06

decade

/div

1E-14

5.000

.0000 V3 .5000/div (V)

1000

100

11 10 100

IOUT (mA)

Voltage Drop (mV) [ VCC - VOUT ]

VCC = 4.5V

VBATTERY = 0V

1000

100

11 10

OUT

(mA)

Voltage Drop (mV) [ V

BATTERY

- V

OUT

]

= 0V

BATTERY

= 4.5V

14000

12000

10000

8000

6000

4000

2000

-60 -35 -10 15 40 65 90 115 140

Temperature (oC)

RESET Output Resistance (Ω )

185

180

175

-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (

Reset Timeout (mS)

10-60 -40 -20 0 20 40 60 80 100 120 140

Temperature (

Propagation Delay (µs)

Figure 15A. SP690A RESET Response Time Figure 15B. Circuit for the SP690A/802L RESET

Response Time

GND

RESET

30pF

10KΩ

= +25 C

Figure 13A. SP690A RESET Output Voltage vs.

Supply Voltage Figure 13B. Circuit for the SP690A/802L RESET

Output Voltage vs. Supply Voltage

Figure 14A. SP805L RESET Output Voltage vs.

Supply Voltage Figure 14B. Circuit for the SP805 RESET Output

Voltage vs. Supply Voltage

GND

RESET

330pF

10KΩ

BATTERY

GND

RESET

330pF

2KΩ

RESET

BATTERY

= 0V

= +25 C

0V 1

div

1 sec / div

RESET

3.1V

[ T ]

1V / div

3.1V

RESET

10µS / div

div

RESET

1 sec /div

Figure 16A. SP805L RESET Response Time Figure 16B. Circuit for the SP805 RESET Response

Time

GND

RESET

330pF

10KΩ

Figure 17B. Circuit for the Power-Fail Comparator

Response Time (fall)

Figure 17A. Power-Fail Comparator Response Time (fall)

30pF

1KΩ

PFO

+1.25V

+5V

PFI

= +5V

= +25 C

Figure 18A. Power-Fail Comparator Response Time (rise) Figure 18B. Circuit for the Power-Fail Comparator

Response Time (rise)

30pF 1KΩ

PFO

+1.25V

+5V

PFI

VCC = +5V

TA = +25 C

PFI

1.3V

1.2V

500ns / div

PFO

= 5V

= 0

BATTERY

11.3V

1.2V V

= 5

= 0

BATTERY

PFI

PFO

500ns / div

[ T ]

1V / div

3.1V

10 µs / div

RESET

Figure 19. Timing Diagram

VCC 0V

3.0V or 3.3V

tWP

RESET

RESET*

PFO

VOUT

3.0V or 3.3V

VSW

BATTERY

=3.6V

VRST

VSW

VBATTERY=PFI=3.6V

IOUT=0mA

*SP804T/S/R and SP805T/S/R only; Reset externally pulled up to VCC.

3.0V or 3.3V

THEORY OF OPERATION

The SP690T/S/R, SP802T/S/R, SP804T/S/R

and SP805T/S/R devices are microprocessor

(µP) supervisory circuits that monitor the power

supplied to digital circuits such as microproces-

sors, microcontrollers, or memory. The series is

an ideal solution for portable, battery-powered

equipment that requires power supply monitoring.

Implementing this series will reduce the

number of components and overall complexity.

The watchdog functions of this product family

will continuously oversee the operational status

of a system.

These µP supervisory circuits are not short-

circuit protected. Shorting VOUT to ground -

excluding power-up transients such as charging

a decoupling capacitor - may potentially damage

these devices. Decouple both VCC and VBATTERY

pins to ground by placing 0.1µF capacitors as

close to the device as possible. The operational

features and benefits of the SP690T/S/R,

SP802T/S/R, SP804T/S/R and SP805T/S/R

devices are described in more detail below.

Reset Output

The microprocessor's (µP's) reset input starts

the µP in a known state. When the µP is in an

unknown state, it should be held in reset. The

SP690T/S/R, SP802T/S/R, SP804T/S/R and

SP805T/S/R devices assert reset during

power-up and prevent code execution errors

during power-down or brownout conditions.

RESET is guaranteed to be a logic LOW for 0V

< VCC < VRST, provided that VBATTERY is greater

than 1V. Without a backup battery, RESET is

guaranteed valid for VCC > 1V. Once VCC

exceeds the reset threshold, an internal timer

keeps RESET low for the reset timeout period.

After this period, RESET goes HIGH, as seen in

Figure 19.

If a brownout condition occurs and VCC dips

below the reset threshold, RESET goes LOW.

Each time RESET is triggered, it stays low for

the reset timeout period. Any time VCC goes

below the reset threshold, the internal timer

restarts.

FEATURES

The SP690T/S/R, SP802T/S/R, SP804T/S/R

and SP805T/S/R devices provide four key

functions:

1. A battery backup switch for CMOS RAM,

CMOS microprocessors, or other logic.

2. A reset output during power-up, power-down

and brownout conditions.

3. A reset pulse if the optional watchdog timer

has not been toggled within a specified time.

4. A 1.25V threshold detector for power-fail

warning, low battery detection, or to monitor a

power supply other than 3.3V or 3.0V.

The SP690T/S/R, SP802T/S/R, SP804T/S/R

and SP805T/S/R devices differ in their reset-

voltage threshold levels and are ideally suited

for applications in automotive systems, intelligent

instruments, and battery-powered computers and

controllers. The series is a solid match for

designs where it is critical to monitor the

power supply to the µP and it’s related digital

components.

Figure 20. Typical Operating Circuit

GND

RESET

NMI

I/O LINE

pin 7*

PFO

WDI

OUT

BUS

GND

BATTERY

Unregulated

Regulated +3.3V or +3.0V

0.1µF

PFI

Lithium

Battery

3.6V

µP

CMOS

RAM

0.1µF

RESET for the SP690T/S/R and the SP802T/S/R

RESET for the SP804T/S/R and the SP805T/S/R

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

The watchdog timer can also initiate a reset.

Refer to the Watchdog Input secti o n .

The SP804T/S/R and SP805T/S/R active-HIGH

RESET output is open drain and the inverse

of the SP690T/S/R and SP802T/S/R RESET

outputs.

RESET is also triggered by a watchdog timeout.

If WDI remains either high or low for a period

that exceeds the watchdog timeout period (1.6

sec), RESET pulses low for 200mS. As long as

RESET is asserted, the watchdog timer remains

cleared. When RESET comes high, the watch-

dog resumes timing and must be serviced within

1.6sec. If WDI is tied high or low, a RESET

pulse is triggered every 1.8sec (tWD plus tRS).

Reset Threshold

The SP690T and SP805T devices are designed

for 3.3V systems with a ±5% power-supply

tolerance and a 10% system tolerance. Except

for watchdog faults, reset will not assert as long

as the power supply remains above 3.15V (3.3V

- 5%). Reset is guaranteed to assert before the

power supply falls below 3.0V.

The SP690S and SP805S devices are designed

for 3.3V ±10% power supplies. Except for

watchdog faults, they are guaranteed not to

assert reset as long as the supply remains above

3.0V (3.3V - 10%). Reset is guaranteed to

assert before the power supply fails below 2.85V

(VCC - 14% ) .

The SP690R and SP805R devices are optimized

for monitoring 3.0V ±10% power supplies. Reset

will not occur until VCC falls below 2.7V (3.0V

- 10%), but is guaranteed to occur before the

supply falls below 2.55V (3.0V - 15%).

The SP802T/S/R and SP804T/S/R devices are

respectively similar to the SP690T/S/R and

SP805T/S/R devices with tightened reset

and power-fail threshold tolerances.

Watchdog Input

The watchdog circuit monitors the µP's activity.

If the µP does not toggle the watchdog input

(WDI) within 1.6sec, a reset pulse is triggered.

The internal 1.6sec timer is cleared by either a

reset pulse or by a transition (LOW-to-HIGH or

HIGH-to-LOW) at WDI. If WDI is tied HIGH

or LOW, a RESET pulse is triggered every

1.8sec (tWD plus tRS).

As long as reset is asserted, the timer remains

cleared and does not count. As soon as reset is

de-asserted, the timer starts counting. Unlike

the 5V SP690A series, the watchdog function

cannot be disabled .

Power-Fail Comparator

The power-fail comparator can be used as an

under-voltage detector to signal the failing of a

power supply (it is completely separate from the

rest of the circuitry and does not need to be

dedicated to this function). The PFI input is

compared to an internal 1.25V. If PFI is less than

VPFT, PFO goes low.

The power-fail comparator turns off and PFO

goes LOW when VCC falls below VSW on

power-down. The power-fail comparator turns

on as VCC crosses VSW on power-up. If the

comparator is not used, connect PFI to ground

and leave PFO unconnected.

Backup-Battery Switchover

In the event of a brownout or power failure, it

may be necessary to preserve the contents of

RAM. With a backup battery installed at

VBATTERY, the devices automatically switch

RAM to backup power when VCC fails.

This family of µP supervisors (designed for

3.3V and 3V systems) doesn't always connect

VBATTERY to VOUT when VBATTERY is greater

than VCC. VBATTERY connects to VOUT (through

a 15Ω switch) when VCC is below VSW and

VBATTERY is greater than VCC.

Switchover at VSW (2.40V) ensures that battery-

backup mode is entered before VOUT gets too

close to the 2.0V minimum required to reliably

retain data in CMOS RAM. Switchover at higher

VCC voltages would decrease backup-battery

life. When VCC recovers, switchover is deferred

until VCC rises above the reset threshold, VRST,

to ensure a stable supply. VOUT is connected to

VCC throu gh a 1. 5Ω PMOS power switch.

Using a High Capacity Capacitor as a

Backup Power Source

Figure 21 shows two ways to use a High Value

Capacitor as a backup power source. The High

Value Capacitor may be connected through a

diode to the 3V input as in Figure 21A or, if a

5V supply is also available, the High Valu e

Capacitor may be charged up to the 5V supply

as in Figure 21B allowing a longer backup

period. Since VBATTERY can exceed VCC while VCC

is above the reset threshold, there are no

special precautions when using these µP

supervisors with a High Value Capacitor.

Operation Without a Backup Power

Source

These µP supervisors were designed for

battery-backed applications. If a backup power

source is not used, connect both VBATTERY

and VOUT to VCC. Since there is no need to

switch over to any backup power source, VOUT

does not need to be switched. A direct connec-

tion to VCC eliminates any voltage drops across

the switch which may push VOUT below VCC.

Replacing the Backup Battery

If VBATTERY is decoupled with a 0.1µF capacitor

to ground, the backup battery can be removed

while VCC remains valid without danger of

triggering RESET/RESET. As long as VCC

stays above VSW, battery-backup mode cannot

be entered.

Adding Hysteresis to the Power-Fail

Comparator

The power-fail comparator has a typical input

hysteresis of 10mV. This is sufficient for most

applications where a power-supply line is being

monitored through an external voltage divider

(refer to the Monitoring an Additional Power

Supply section).

If additional noise margin is desired, connect a

resistor between PFO and PFI as shown in

Figure 22A. Select the ratio of R1 and R2 such

that PFI sees 1.25V when VIN falls to its trip

point (VTRIP). R3 adds the hysteresis and will

typically be more than 10 times the value of R1

or R2. The hysteresis window extends both

above (VH) and below (VL) the original trip

point (VTRIP).

3.0V or 3.3V

GND

BATTERY V

OUT

CONNECT TO

STATIC RAM

TO µP

0.1F CONNECT

pin 7*

1N4148

3.0V or 3.3V

GND

BATTERY

OUT

RESET for the SP690T/S/R and the SP802T/S/R

RESET for the SP804T/S/R and the SP805T/S/R

CONNECT TO

STATIC RAM

TO µP

0.1F CONNECT

pin 7*

1N4148

+5V

Figure 21. Using a High Capacity Capacitor as a Backup Power Source

A) B)

Connecting an ordinary signal diode in series

with R3, as in Figure 22B, causes the lower trip

point (VL) to coincide with the trip point without

hysteresis (VTRIP), so the entire hysteresis

window occurs above VTRIP. This method pro-

vides additional noise margin without compro-

mising the accuracy of the power-fail threshold

when the monitored voltage is falling. It is

useful for accurately detecting when a voltage

falls past a threshold.

Figure 22A. Adding Additional Hysteresis to the Power-Fail Comparator.

Figure 22B. Shifting the Additional Hysteresis above VPFT

The current through R1 and R2 should be at least

1µA to ensure that the 25nA (max over extended

temperature range) PFI input current does not

shift the trip point. R3 should be larger than

10kΩ so it does not load down the PFO pin.

Capacitor C1 adds additional noise rejection.

Figure 23. Using the Power-Fail Comparator to Monitor an Additional Power Supply

VIN

TOµP

PFI

PFO GND

VCC

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

PFO

0V 0V VL VTRIP VH

VIN

TOµP

PFI

PFO GND

VCC

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

PFO

0V 0V VTRIP VH

VIN

*OPTIONAL

VTRIP = VPFT

VH =

VL = R1

WHERE VPFT = 1.25V

VPFH = 10mV

R1 + R2

( )

VPFT + VPFH

( )

1 + 1 + 1

R1 R2 R3

( )

VPFT

[ (

1 + 1 + 1

R1 R2 R3

)

- VCC

]

VTRIP = VPFT

VL = R1

WHERE VPFT = 1.25V

VPFH = 10mV

VD = DIOD FORWARD VOLTAGE DROP

R1 + R2

( )

VPFT + VPFH

[ ( 1 + 1 + 1

R1 R2 R3)- (V

CC - VD)

R3 ]

( )

*C1 *C1

V-

PFI PFO

GND

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

PFO

TRIP

V-

PFI PFO

GND

SP690T/S/R

SP802T/S/R

SP804T/S/R

SP805T/S/R

PFO

TRIP

3.0V OR 3.3V

TRIP

= R2

WHERE V

PFT

= 1.25V

PFH

= 10mV

NOTE: V

TRIP

IS NEGATIVE

PFT

+ V

PFH

( )

1 + 1

R1 R2

( )

PFT

[ (

1 + 1

R1 R2

)

- V

]

[

- V

]

TRIP

= V

PFT

R1 + R2

( )

PFT

+ V

PFH

(

R1 + R2

)

( )

A.) B.)

Figure 24. Interfacing to Microprocessors with

Bidirectional RESET I/O

GND

RESET RESET

4.7KΩ

µP

Buffered RESET connects to System Components

Monitoring an Additional Power Supply

These µP supervisors can monitor either positive

or negative supplies using a resistor voltage

divider to PFI. PFO can be used to generate an

interrupt to the µP, as seen in Figure 23.

Interfacing to µPs with Bidirectional

Reset Pins

Any µPs with bidirectional reset pins, such as

the Motorola 68HC11 series, can interface with

the SP690_ and the SP802_ RESET outputs.

For example, if the RESET output is driven

HIGH and the µP wants to pull it LOW,

indeterminate logic levels may result. To correct

this, connect a 4.7kΩ resistor between the

RESET output and the µP reset I/O, as in

Figure 24. Buffer the RESET output to other

system components.

Negative-Going VCC Transients

While issuing resets to the µP during power-up,

power-down, and brownout conditions, these

supervisors are relatively immune to short-

duration negative-going VCC transients

(glitches). It is usually undesirable to reset the

µP when VCC experiences only small glitches.

Figure 25 shows maximum transient duration

vs. reset-comparator overdrive, for which reset

pulses are not generated. The data was generated

using negative-going VCC pulses, starting at

3.3V and ending below the reset threshold by

the magnitude indicated (reset comparator

overdrive). The graph shows the maximum pulse

width a negative-going VCC transient may

typically have without causing a reset pulse to

be issued. As the amplitude of the transient

increases (i.e. goes farther below the reset

threshold), the maximum allowable pulse width

decreases. Typically, a VCC transient that goes

100mV below the reset threshold and lasts for

40µs or less will not cause a reset pulse to be

issued. A 100nF bypass capacitor mounted close

to the VCC pin provides additional transient

immunity.

Figure 25. Maximum Transient Duration without

Causing a Reset Pulse vs. Reset Comparator Overdrive

1nF Capacitor

VOUT TO GND

Above Line

RESET

Generated

RESET

Generated

ALTERNATE

END PINS

(BOTH ENDS)

D1 = 0.005" min.

(0.127 min.)

PACKAGE: PLASTIC

DUAL–IN–LINE

(NARROW)

DIMENSIONS (Inches)

Minimum/Maximum

(mm)

A = 0.210" max.

(5.334 max).

LA2

A1 = 0.015" min.

(0.381min.)

e = 0.100 BSC

(2.540 BSC) e

= 0.300 BSC

(7.620 BSC)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.735/0.775

(18.669/19.685)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.355/0.400

(9.017/10.160)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

22–PIN8–PIN 14–PIN 16–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

1.145/1.155

(29.083/29.337)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.780/0.800

(19.812/20.320)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

18–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.880/0.920

(22.352/23.368)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

20–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.980/1.060

(24.892/26.924)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

E H

PACKAGE: PLASTIC

SMALL OUTLINE (SOIC)

(NARROW)

DIMENSIONS (Inches)

Minimum/Maximum

(mm) 8–PIN

h x 45°

0.053/0.069

(1.346/1.748)

0.004/0.010

(0.102/0.249

0.014/0.019

(0.35/0.49)

0.189/0.197

(4.80/5.00)

0.150/0.157

(3.802/3.988)

0.050 BSC

(1.270 BSC)

0.228/0.244

(5.801/6.198)

0.010/0.020

(0.254/0.498)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

14–PIN

0.053/0.069

(1.346/1.748)

0.004/0.010

(0.102/0.249)

0.013/0.020

(0.330/0.508)

0.337/0.344

(8.552/8.748)

0.150/0.157

(3.802/3.988)

0.050 BSC

(1.270 BSC)

0.228/0.244

(5.801/6.198)

0.010/0.020

(0.254/0.498)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

16–PIN

0.053/0.069

(1.346/1.748)

0.004/0.010

(0.102/0.249)

0.013/0.020

(0.330/0.508)

0.386/0.394

(9.802/10.000)

0.150/0.157

(3.802/3.988)

0.050 BSC

(1.270 BSC)

0.228/0.244

(5.801/6.198)

0.010/0.020

(0.254/0.498)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

ORDERING INFORMATION

Model Temperature Range Package Types

SP690TCN......................................................0°C to +70°C......................................................8-Pin NSOIC

SP690TCP......................................................0°C to +70°C.........................................................8-Pin PDIP

SP690TEN.....................................................-40°C to +85°C....................................................8-Pin NSOIC

SP690TEP.....................................................-40°C to +85°C.......................................................8-Pin PDIP

SP690SCN......................................................0°C to +70°C......................................................8-Pin NSOIC

SP690SCP......................................................0°C to +70°C.........................................................8-Pin PDIP

SP690SEN.....................................................-40°C to +85°C....................................................8-Pin NSOIC

SP690SEP.....................................................-40°C to +85°C.......................................................8-Pin PDIP

SP690RCN......................................................0°C to +70°C......................................................8-Pin NSOIC

SP690RCP......................................................0°C to +70°C.........................................................8-Pin PDIP

SP690REN.....................................................-40°C to +85°C....................................................8-Pin NSOIC

SP690REP.....................................................-40°C to +85°C.......................................................8-Pin PDIP

SP802TCN........................................................0°C to +70°C.................................................. ..8-Pin NSOIC

SP802TCP........................................................0°C to +70°C.......................................................8-Pin PDIP

SP802TEN.......................................................-40°C to +85°C..................................................8-Pin NSOIC

SP802TEP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

SP802SCN........................................................0°C to +70°C....................................................8-Pin NSOIC

SP802SCP........................................................0°C to +70°C.......................................................8-Pin PDIP

SP802SEN.......................................................-40°C to +85......................................................8-Pin NSOIC

SP802SEP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

SP802RCN........................................................0°C to 0°C........................................................8-Pin NSOIC

SP802RCP........................................................0°C to+70°C...................................................... 8-Pin PDIP

SP802REN.......................................................-40°C to +85°C..................................................8-Pin NSOIC

SP802REP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

SP804TCN.......................................................0°C to +70°C................................................... ..8-Pin NSOIC

SP804TCP.......................................................0°C to +70°C........................................................8-Pin PDIP

SP804TEN......................................................-40°C to +85°C................................................. ..8-Pin NSOIC

SP804TEP......................................................-40°C to +85°C......................................................8-Pin PDIP

SP804SCN.......................................................0°C to +70°C.....................................................8-Pin NSOIC

SP804SCP.......................................................0°C to +70°C........................................................8-Pin PDIP

SP804SEN......................................................-40°C to +85°C...................................................8-Pin NSOIC

SP804SEP......................................................-40°C to +85°C......................................................8-Pin PDIP

SP804RCN.......................................................0°C to +70°C.....................................................8-Pin NSOIC

SP804RCP.......................................................0°C to +70°C........................................................8-Pin PDIP

SP804REN......................................................-40°C to +85°C...................................................8-Pin NSOIC

SP804REP......................................................-40°C to +85°C......................................................8-Pin PDIP

SP805TCN........................................................0°C to +70°C.................................................. ..8-Pin NSOIC

SP805TCP........................................................0°C to +70°C.......................................................8-Pin PDIP

SP805TEN.......................................................-40°C to +8C.................................................. ..8-Pin NSOIC

SP805TEP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

SP805SCN........................................................0°C to+70°C.....................................................8-Pin NSOIC

SP805SCP........................................................0°C to +70°C.......................................................8-Pin PDIP

SP805SEN.......................................................-40°C to +85°C..................................................8-Pin NSOIC

SP805SEP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

SP805RCN........................................................0°C to +70°C....................................................8-Pin NSOIC

SP805RCP........................................................0°C to +70°C.......................................................8-Pin PDIP

SP805REN.......................................................-40°C to +85°C..................................................8-Pin NSOIC

SP805REP.......................................................-40°C to +85°C.....................................................8-Pin PDIP

Please consult the factory for pricing and availability on a Tape-On-Reel option.

Corporation

SIGNAL PROCESSING EXCELLENCE

Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the

application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.

Sipex Corporation

Headquarters and

Sales Office

22 Linnell Circle

Billerica, MA 01821

TEL: (978) 667-8700

FAX: (978) 670-9001

e-mail: sales@sipex.com

Sales Office

233 South Hillview Drive

Milpitas, CA 95035

TEL: (408) 934-7500

FAX: (408) 935-7600