LTC3576EUFE-1#PBF Linear Technology, LTC3576EUFE-1#PBF Datasheet - Page 22

LTC3576EUFE-1#PBF

Manufacturer Part Number

LTC3576EUFE-1#PBF

Description

IC POWER MANAGER W/USB OTG 38QFN

Manufacturer

Linear Technology

Datasheet

1.LTC3576EUFEPBF.pdf (48 pages)

Specifications of LTC3576EUFE-1#PBF

Applications

Handheld/Mobile Devices

Voltage - Supply

4.35 V ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

38-QFN

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Supply

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Part Number:

LTC3576EUFE-1#PBFLTC3576EUFE-1

Manufacturer:

Quantity:

10 000

Company:

Part Number:

LTC3576EUFE-1#PBF

Manufacturer:

LINEAR/凌特

Quantity:

20 000

Company:

Part Number:

LTC3576EUFE-1#PBF/IU

Manufacturer:

Quantity:

929

Current page: 22 of 48
Download datasheet (584Kb)

LTC3576/LTC3576-1

proaches this limit CLPROG servos to 1.15V and V

rapidly to V

be sufﬁ cient negative slope on the inductor current when

the PMOS switch is on to balance the rise in the inductor

current when the NMOS switch is on. This will cause the

inductor current to run away and the voltage on CLPROG

to rise. When CLPROG reaches 1.2V the switching of the

synchronous PMOS is terminated and V

statically to its gate. This ensures that the inductor current

will have sufﬁ cient negative slope during the time current

is ﬂ owing to the output. The PMOS will resume switching

when CLPROG drops down to 1.15V.

The LTC3576/LTC3576-1 maintain voltage regulation even

if V

PMOS switch. The PMOS switch is enabled when V

rises above V

below V

running away when not in current limit. Since the PMOS

no longer acts as a low impedance switch in this mode,

there will be more power dissipation within the IC. This

will cause a sharp drop in efﬁ ciency.

If V

for more than 7.2ms a short-circuit fault will be declared

and the part will shut off. The CHRG pin will blink at 35kHz

with a duty cycle that varies between 12% and 88% at a

4Hz rate. See Table 2. To re-enable step-up mode, the

ENOTG pin or, with ENOTG grounded, the B0 bit in the

Bat-Track Auxiliary High Voltage Switching Regulator

Control

The WALL, ACPR and V

with an external high voltage step-down switching regula-

tor such as the LT

production when operating from higher voltage sources,

as shown in Figures 1 and 3. Bat-Track control circuitry

regulates the external switching regulator’s output voltage

to the larger of (BAT + 300mV) or 3.6V. This maximizes

battery charger efﬁ ciency while still allowing instant-on

operation when the battery is deeply discharged.

The feedback network of the high voltage regulator should

be set to generate an output voltage between 4.5V and

5.5V. When high voltage is applied to the external regulator,

OPERATION

C port must be cycled low and then high.

OUT

BUS

is above V

is less than 4V and the PMOS switch is disabled

OUT

+ 70mV to prevent the inductor current from

OUT

. When V

+ 180mV and is disabled when it falls

BUS

3480 or the LT3653 to minimize heat

. This is achieved by disabling the

BUS

pins can be used in conjunction

is close to V

OUT

there may not

is applied

BUS

falls

BUS

WALL will rise toward this programmed output voltage.

When WALL exceeds approximately 4.3V, ACPR is brought

low and the Bat-Track control of the LTC3576/LTC3576-1

overdrives the local V

age step-down switching regulator. Therefore, once the

Bat-Track control is enabled, the output voltage is set in-

dependent of the switching regulator feedback network.

Bat-Track control provides a signiﬁ cant efﬁ ciency advantage

over the simple use of a 5V switching regulator output to

drive the battery charger. With a 5V output driving V

battery charger efﬁ ciency is approximately:

where η

regulator and 5V is the output voltage of the switching

regulator. With a typical switching regulator efﬁ ciency of

87% and a typical battery voltage of 3.8V, the total bat-

tery charger efﬁ ciency is approximately 66%. Assuming

a 1A charge current, 1.7W of power is dissipated just to

charge the battery!

With Bat-Track, battery charger efﬁ ciency is approxi-

mately:

With the same assumptions as above, the total battery

charger efﬁ ciency is approximately 81%. This example

works out to less than 1W of power dissipation, or almost

60% less heat.

See the Typical Applications section for complete circuits

using the LT3480 and the LT3653 with Bat-Track control.

Ideal Diode(s) from BAT to V

The LTC3576/LTC3576-1 each have an internal ideal diode as

well as a controller for an optional external ideal diode. Both

the internal and the external ideal diodes are always on and

will respond quickly whenever V

If the load current increases beyond the power allowed

from the switching regulator, additional power will be

pulled from the battery via the ideal diode(s). Further-

more, if power to V

TOTAL

BUCK

= η

is the efﬁ ciency of the high voltage switching

BUCK

BUS

•

(USB or wall adapter) is removed,

BAT

control of the external high volt-

BAT

+ 0.3V

OUT

drops below BAT.

3576fb

OUT

LTC3576EUFE-1#PBF Linear Technology, LTC3576EUFE-1#PBF Datasheet - Page 22

LTC3576EUFE-1#PBF

Specifications of LTC3576EUFE-1#PBF

Available stocks

Related parts for LTC3576EUFE-1#PBF