SGS Thomson Microelectronics ST3M01DTR, ST3M01D Datasheet

ST3M01

TRIPLE VOLTAGE REGULATOR

■ ONLY TWO CELL NEED AS INPUT

■ THREE REGULATED OUTPUT

1) HIGH EFFICENCY PFM DC/DC
CONVERTER 3.3V AT 200mA (87%
EFFICENCY)

2) VERY LOW NOISE AND VERY LOW
DROP V

(3V AT 20mA)

REG

3) VERY LOW NOISE AAND VERY LOW
DROP V

■ LOGIC CONTROLLED ELECTRONIC

(1.9 V AT 20m A)

REG

SHUTDOWN

■ LOW BATTERY DETECTOR

■ VIRTUAL GND PIN

■ TEMPERATURA RANGE: -40 TO 85°C

SO-14

SCHEMATIC DIAGRAM

Vin

On-Mode

Off-Mode

100 nF

1 KΩ

150 µF

IN_Linear

SHDN

Vref

IN_SW

15 µH

GND_SW

DC/DC

DC/DC

Ref

Ref

Lx

Linear B

-

+

OUT DC/DC

150 µF

Linear A

GND_Signal

OUT LA

1 µF

OUT LB

1 µF

Virtual GND

LBO

1/11November 2000

ST3M01

ABSOLUTE MAXIMUM RATINGS

Symbol Parameter Value Unit

V

V

SHDN

V

V

LBO

V

virtua l_ GND

I

LBO

I

virtual_GND

T

T

THERMAL DATA

Symbol Parameter Value Unit

R

thj-amb

ORDER CODES

LX

stg

op

DC Input Voltage (Both IN_Linear and IN_SW)

IN

Shutdown Input Voltage -0.3 to VIN+0.3
Switch Voltage
Low Battery Output Voltage
Virtual GND Output Voltage
Low Battery Output Maximum Current
Virtual GND Output Maximum Current
Storage Temperature Range

Operating Junction Temperature Range

Thermal Resistance Junction-ambient (*)

-0.3 to 7 V

-0.3 to 7 V

-0.3 to 7 V

-0.3 to 7 V
30 mA
30 mA

-65 to +150 °C

-40 to +85 °C

160 °C/W

V

Type Package Comment

ST3M01D SO-14 50 parts per tube / 20 tube per box

ST3M01DTR SO-14 (Tape & Reel) 2500 parts per reel

2/11

CONNECTION DIAGRAM (top view)

PIN DESCRIPTION

Pin N° Symbol Name and Function

1 GND SW Switching Ground. Must be low impedance; solder directly to GND plane
2 GND SW Switching Ground. Must be low impedance; solder directly to GND plane
3 Virtual GND Virtual GND. Open Drain N-Cnannel MOSFET: must be high impedance when the

Low Battery condition is detected.

4 LBO Low Battery Output. Open Drain N-Cnannel MOSFET: sinks current when the

input voltage drops below 2V typically.

5V

REF

Reference Voltage Output. Bypass with 0.1 µF to improve the linears V
thermal noise performance

.

6 IN Linear Linear Input. Must be connected togheter with IN SW to the input supply.
7OUT L

8 SHDN

Linear B Output port. 1.9V typically.

B

Shutdown Input. Disables the SMPS and L
referencevoltage and the low batery comparator remain active.

9 GND Signal Signal GND. Must be connected togheter with the Switching Ground.

10 OUT L
11 OUT DC/DC DC/DC Output Port: 3.3V typically.

12 IN SW SMPS Input. Must be connected togheter with IN_Linear to the input supply.
13 LX 1.5A N-Channel Power MOSFET Drain.
14 LX 1.5A N-Channel Power MOSFET Drain.

Linear A Output port. 3V typically.

A

output, but the L

A

ST3M01

REF

, the

B

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ST3M01

ELECTRICAL CHARACTERISTICS (Unless otherwise specified, please refer to the typical operating

circut of the pag 1 for the external components values and connections. Unless otherwise noted

=HIGH)

V

SHDN

Symbol Parameter Test Conditions Min. Typ. Max. Unit

V

V

O(DC/DC)

ν DC/DC Converter Efficency V

V

O(LA)

V

O(LB)

e

N(LA)

e

N(LB)

I

q(OFF)

I

q(OFF)

I

S(DC/DC)

I

q(LA)

I

q(LB)

V

BATT

V

BATT(HYS)

R

ON(LBO)

V

V

T

on

R

ON(V_GND)

Note 1: For VIN < 1.9V the V
Note 2: V

Operating Input Voltage 1.9 3.3 V

I

DC/DC Converter Output
Voltage (Test Circuit A)

Linear A Output Voltage
(Test Circuit A)

Linear B Output Voltage
(Test Circuit A)

Linear A Thermal Output
Noise Voltage (Note 2)

Linear B Thermal Output
Noise Voltage (Note 2)

Quiescent Current OFF
Mode DC/DC & L

OFF LB

A

ON) (Test Circuit E)
Quiescent Current OFF

Mode (DC/DC & L

OFF LB

A

ON) (Test Circuit F)
DC/DC Supply Current

2.24<VIN<3.3V; 0<I
0<I

-40 < T

I

<20mA; 0<I

O(LA)

< 85 °C

J

=2.4V; I

IN

=0mA; I

O(LA)

O(DC/DC)

=0mA; TJ = 25°C

O(LB)

2.24<VIN<3.3V; 0<I
0<I

-40 < T

<20mA; 0<I

O(LA)

< 85°C

J

2.24<VIN<3.3V; 0<I
0<I

-40 < T
VIN=2.4V; V

I
C

VIN=2.4V; V
I
C

V
T

V
T

<20mA; 0<I

O(LA)

< 85°C

J

=20mA; 10 < f < 80KHz;

O(LA)

=1µF; C

O(LA)

=20mA; 10 < f < 80KHz;

O(LB)

=1µF; C

O(LB)

=3.3V; No Load; V

IN

= 25°C

J

=1.9V; No Load; V

IN

= 25°C

J

O(DC/DC)

=0.1µF; TJ = 25°C

REF

O(DC/DC)

=0.1µF; TJ = 25°C

REF

O(DC/DC)
O(LB)

O(DC/DC)
O(LB)

O(DC/DC)
O(LB)

<200mA;

<20mA;

=100mA;

<200mA;

<20mA;

<200mA;

<20mA;

=3.5V;

=3.5V;

=LOW;

SHDN

=HIGH;

SHDN

VIN=2.24V; No Load; TJ = 25°C 100 µA

3.2 3.3 3.415 V

87 %

2.93 3 3.09 V

1.86 1.9 1.955 V

60 µV

35 µV

75 µA

50 µA

(Test Circuit B)
Linear A Quiescent Current

(Test Circuit C)
Linear B Quiescent Current

(Test Circuit C)
Low Battery Detection

Range
Low Battery Detection

VIN=2.24V; V
I

=10mA; TJ = 25°C

O(LA)

VIN=2.24V; V
I

=10mA; TJ = 25°C

O(LB)

V

=HIGH with falling edge 1.96 2 2.04 V

SHDN

O(DC/DC)

O(DC/DC)

=3.5V;

=3.5V;

220 µA

75 µA

150 200 mV

Hysteresys
LBO R

DSON

Control Input Logic Low VIN>2.24V; -40 < TJ < 85°C 0.4 V

ih

Control Input Logic High VIN>2.24V; -40 < TJ < 85°C 1.5 V

il

Timer On Response Time
on DC/DC

VIN=1.9V; ID=5mA; TJ = 25°C 10 Ω

VIN=2.4V; CO=100µF; TJ = 25°C
I

O(DC/DC)

V

=200mA

=from GND to V

SHDN

SHDN(MAX)

0.6 9 ms

Virtual GND RDSON VIN>2.24V; ID=5mA; TJ = 25°C 10 Ω

is out of regul ation because of under dropout con di tion

= 3.5V force for an extern al DC source t o avoid switching noise

O(DC/DC)

O(LB)

rms

rms

4/11