LTC3586EUFE#TRPBF Datasheet LTC3586EUFE#PBF, LTC3586EUFE-1#PBF, LTC3586EUFE-1#TRPBF | P10-P12

LTC3586/LTC3586-1

3586fb

TEMPERATURE (°C)

–55

11.0

(µA)

11.5

12.5

13.0

13.5

–15

45 125

3586 G31

12.0

–35 5

105

14.0

IN1

= 3V

IN3

= 4.5V

IN3

= 3.6V

IN3

(V)

2.7

REDUCTION BELOW 1A (mA)

100

150

200

250

300

3.1 3.5 3.9 4.3

3586 G32

4.7

STEADY STATE ILOAD

START-UP WITH A

RESISTIVE LOAD

START-UP WITH A

CURRENT SOURCE LOAD

OUT3

= 3.3V

TYPE 3 COMPENSATION

Typical perForMance characTerisTics

Buck-Boost Regulator Burst Mode

Operation Quiescent Current

Reduction in Current

Deliverability at Low V

IN3

Buck-Boost Step Response

Boost Efﬁciency (V

IN4

= 3.8V)

Boost Efﬁciency vs V

IN4

Boost Output Voltage

vs Temperature

INPUT VOLTAGE V

IN4

(V)

2.6

EFFICIENCY (%)

100

3 5 5.43.4 3.8 4.2

3586 G35

4.6

VOUT4

= 300mA

OUT4

= 5V

SYNCH

PMOS

OFF

TEMPERATURE (ºC)

–45

4.950

4.985

4.980

4.975

4.970

4.965

4.960

4.955

4.995

4.990

5.000

–30 –15 0 3015

3586 G36

45 60 75 90

OUT4

(V)

IN4

= 2.7V

IN4

= 3.8V

IN4

= 4.5V

Maximum Deliverable Boost

Output Current

Maximum Boost Duty Cycle

vs V

IN4

Boost Step Response

(50mA to 300mA)

IN4

(V)

2.7

OUTPUT CURRENT I

VOUT4

(mA)

2200

2000

1800

1600

1400

1200

1000

800

600

400

200

3 3.3 3.6 3.9

3586 G37

4.2 4.5

T = 90ºC

T = –45ºC

L = 2.2µH

OUT4

= 4.9V (SET FOR 5V)

T = 25ºC

IN4

(V)

2.7

MAXIMUM DUTY CYCLE (%)

100

3 3.3 3.6 3.9 4.2 4.5

3586 G38

T = 90ºC

T = 25ºC

T = –45ºC

= 25°C unless otherwise noted.)

100µs/DIV

OUT3

100mV/DIV

COUPLED

300mA

VOUT3

200mA/DIV

3586 G33

IN3

= 3.8V

OUT3

= 3.3V

VOUT4

(mA)

EFFICIENCY (%)

POWER LOSS (W)

10 100 1000

3586 G23

100

0.1

0.2

0.3

0.4

0.5

0.6

0.7

OUT4

= 5V

EFFICIENCY

POWER LOSS

50µs/DIV

OUT4

100mV/DIV

COUPLED

IN4

= 3.8V

OUT4

= 5V

L = 2.2µH

C = 10µF

300mA

50mA

VOUT4

125mA/DIV

3586 G39

IN3

= 3.8V

OUT3

= 3.3V

LTC3586/LTC3586-1

3586fb

pin FuncTions

LIM0

, I

LIM1

(Pins 1, 2): Logic Inputs. I

LIM0

and I

LIM1

control the current limit of the PowerPath switching

regulator. See Table 1.

SW4 (Pin 8): Switch Node for the (Boost) Switching

Regulator 4. An external inductor connects between this

pin and V

IN4

MODE (Pin 9): Digital Input. The MODE pin controls dif-

ferent modes of operation for the switching regulators

according to Table 2.

Table 1. USB Current Limit Settings

LIM1

) (I

LIM0

) USB SETTING

0 0 1x Mode (USB 100mA Limit)

0 1 10x Mode (Wall 1A Limit)

1 0 Suspend

1 1 5x Mode (USB 500mA Limit)

LDO3V3 (Pin 3): 3.3V LDO Output Pin. This pin provides

a regulated always-on 3.3V supply voltage. LDO3V3

gets its power from V

OUT

. It may be used for light loads

such as a watch dog microprocessor or real time clock.

A 1µF capacitor is required from LDO3V3 to ground. If

the LDO3V3 output is not used it should be disabled by

connecting it to V

OUT

CLPROG (Pin 4): USB Current Limit Program and Moni-

tor Pin. A resistor from CLPROG to ground determines

the upper limit of the current drawn from the V

BUS

pin.

A fraction of the V

BUS

current is sent to the CLPROG pin

when the synchronous switch of the PowerPath switching

regulator is on. The switching regulator delivers power until

the CLPROG pin reaches 1.188V. Several V

BUS

current limit

settings are available via user input which will typically

correspond to the 500mA and 100mA USB speciﬁcations.

A multilayer ceramic averaging capacitor is required at

CLPROG for ﬁltering.

NTC (Pin 5): Input to the Thermistor Monitoring Circuits.

The NTC pin connects to a battery’s thermistor to deter-

mine if the battery is too hot or too cold to charge. If the

battery’s temperature is out of range, charging is paused

until it re-enters the valid range. A low drift bias resistor

is required from V

BUS

to NTC and a thermistor is required

from NTC to ground. If the NTC function is not desired,

the NTC pin should be grounded.

OUT4

(Pins 6, 7): Power Output for the (Boost) Switching

Regulator 4. A 10µF MLCC capacitor should be placed as

close to the pins as possible.

Table 2. Switching Regulators Mode

REGULATION MODE

Mode Buck Buck-Boost Boost

0 Pulse-Skip PWM Pulse-Skip

1 Burst Burst Pulse-Skip

FB4 (Pin 10): Feedback Input for the (Boost) Switching

Regulator 4. When the control loop is complete, the volt-

age on this pin servos to 0.8V.

FB3 (Pin 11): Feedback Input for (Buck-Boost) Switching

Regulator 3. When regulator 3’s control loop is complete,

this pin servos to 0.8V.

(Pin 12): Output of the Error Ampliﬁer and Voltage Com-

pensation Node for (Buck-Boost) Switching Regulator 3.

External Type I or Type III compensation (to FB3) connects

to this pin. See the Applications Information section for

selecting buck-boost compensation components.

SWAB3 (Pin 13): Switch Node for (Buck-Boost) Switch-

ing Regulator 3. Connected to Internal Power Switches A

and B. An external inductor connects between this node

and SWCD3.

IN3

(Pins 14, 15): Power Input for (Buck-Boost) Switching

Regulator 3. These pins will generally be connected to V

OUT

A 1µF MLCC capacitor is recommended on these pins.

OUT3

(Pins 16, 17): Output Voltage for (Buck-Boost)

Switching Regulator 3.

EN3 (Pin 18): Digital Input. This input enables the

buck-boost switching regulator 3.

SWCD3 (Pin 19): Switch Node for (Buck-Boost) Switch-

ing Regulator 3 Connected to Internal Power Switches C

and D. An external inductor connects between this node

and SWAB3.

LTC3586/LTC3586-1

3586fb

pin FuncTions

EN2 (Pin 20): Digital Input. This input enables the buck

switching regulator 2.

EN1 (Pin 21): Digital Input. This input enables the buck

switching regulator 1.

IN4

(Pin 22): Power Input for Switching Regulator 4

(Boost). This pin will generally be connected to V

OUT

A 1µF MLCC capacitor is recommended on this pin.

FB2 (Pin 23): Feedback Input for (Buck) Switching Regu-

lator 2. When regulator 2’s control loop is complete, this

pin servos to 0.8V.

IN2

(Pin 24): Power Input for (Buck) Switching Regu-

lator 2. This pin will generally be connected to V

OUT

A 1µF MLCC capacitor is recommended on this pin.

SW2 (Pin 25): Power Transmission Pin for (Buck) Switch-

ing Regulator 2.

SW1 (Pin 26): Power Transmission Pin for (Buck) Switch-

ing Regulator 1.

IN1

(Pin 27): Power Input for (Buck) Switching Regula-

tor 1. This pin will generally be connected to V

OUT

. A 1µF

MLCC capacitor is recommended on this pin.

FB1 (Pin 28): Feedback Input for (Buck) Switching Regu-

lator 1. When regulator 1’s control loop is complete, this

pin servos to 0.8V.

PROG (Pin 29): Charge Current Program and Charge

Current Monitor Pin. Connecting a resistor from PROG

to ground programs the charge current. If sufﬁcient in-

put power is available in constant-current mode, this pin

servos to 1V. The voltage on this pin always represents

the actual charge current.

CHRG (Pin 30): Open-Drain Charge Status Output. The

CHRG pin indicates the status of the battery charger. Four

possible states are represented by CHRG: charging, not

charging, unresponsive battery and battery temperature

out of range. CHRG is modulated at 35kHz and switches

between a low and a high duty cycle for easy recogni-

tion by either humans or microprocessors. See Table 3.

CHRG requires a pull-up resistor and/or LED to provide

indication.

GATE (Pin 31): Analog Output. This pin controls the gate

of an optional external P-channel MOSFET transistor used

to supplement the ideal diode between V

OUT

and BAT. The

external ideal diode operates in parallel with the internal

ideal diode. The source of the P-channel MOSFET should

be connected to V

OUT

and the drain should be connected

to BAT. If the external ideal diode FET is not used, GATE

should be left ﬂoating.

BAT (Pin 32):

Single Cell Li-Ion Battery Pin. Depending on

available V

BUS

power, a Li-Ion battery on BAT will either

deliver power to V

OUT

through the ideal diode or be charged

from V

OUT

via the battery charger.

EN4 (Pin 33): Digital Input. This input enables the boost

switching regulator 4.

OUT

(Pin 34): Output Voltage of the Switching

PowerPath Controller and Input Voltage of the Battery

Charger. The majority of the portable product should be

powered from V

OUT

. The LTC3586/LTC3586-1 will partition

the available power between the external load on V

OUT

and

the internal battery charger. Priority is given to the external

load and any extra power is used to charge the battery. An

ideal diode from BAT to V

OUT

ensures that V

OUT

is powered

even if the load exceeds the allotted power from V

BUS

if the V

BUS

power source is removed. V

OUT

should be

bypassed with a low impedance ceramic capacitor.

BUS

(Pins 35, 36): Primary Input Power Pin. These

pins deliver power to V

OUT

via the SW pin by drawing

controlled current from a DC source such as a USB port

or wall adapter.

SW (Pin 37): Power Transmission Pin for the USB

Power Path. The SW pin delivers power from V

BUS

to V

OUT

via the buck switching regulator. A 3.3µH inductor should

be connected from SW to V

OUT

FAULT (Pin 38): Bi-directional input/output (open-drain)

used to alert or receive information from other power

management ICs regarding an electrical fault.

GND (Exposed Pad Pin 39): Ground. The exposed pad

should be connected to a continuous ground plane on the

second layer of the printed circuit board by several vias

directly under the LTC3586/LTC3586-1.

P1-P3 P4-P6 P7-P9 P10-P12 P13-P15 P16-P18 P19-P21 P22-P24 P25-P27 P28-P30 P31-P33 P34-P36

LTC3586EUFE#TRPBF

Mfr. #:

Buy LTC3586EUFE#TRPBF

Manufacturer:

Analog Devices / Linear Technology

Description:

Battery Management High Efficiency USB Power Manager + Dual Buck + Boost + Buck/Boost DC/DC

Lifecycle:

New from this manufacturer.

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LTC3586EUFE#TRPBF

LTC3586EUFE#TRPBF

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