LTC3550EDHC-1#TR Linear Technology, LTC3550EDHC-1#TR Datasheet - Page 19

LTC3550EDHC-1#TR

Manufacturer Part Number

LTC3550EDHC-1#TR

Description

IC,Battery Management,CMOS,LLCC,16PIN,PLASTIC

Manufacturer

Linear Technology

Type

Battery Chargerr

Datasheet

1.LTC3550EDHC-1TR.pdf (24 pages)

Specifications of LTC3550EDHC-1#TR

Battery Type

Li-Ion

Output Current

800mA

Output Voltage

4.2V

Operating Supply Voltage (min)

2.5V

Operating Supply Voltage (max)

5.5V

Operating Temp Range

-40C to 85C

Mounting

Surface Mount

Pin Count

Operating Temperature Classification

Industrial

Lead Free Status / Rohs Status

Not Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Part Number:

LTC3550EDHC-1#TRLTC3550EDHC-1#PBF

Manufacturer:

LINEAR/凌特

Quantity:

20 000

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However, the user may wish to repeat the previous analysis

to take the buck regulator’s power dissipation into account.

Equation (6) can be modiﬁ ed to take into account the

temperature rise due to the buck regulator:

For optimum performance, it is critical that the exposed

metal pad on the backside of the LTC3550-1 package is

properly soldered to the PC board ground. When correctly

soldered to a 2500mm

the LTC3550-1 has a thermal resistance of approximately

40°C/W. Failure to make thermal contact between the ex-

posed pad on the backside of the package and the copper

board will result in thermal resistances far greater than

40°C/W. As an example, a correctly soldered LTC3550-1

can deliver over 800mA to a battery from a 5V supply

at room temperature. Without a good backside thermal

connection, this number would drop to much less than

500mA.

Battery Charger Stability Considerations

The constant-voltage mode feedback loop is stable without

any compensation provided a battery is connected to the

charger output. When the charger is in constant-current

mode, the charge current program pin (IDC or IUSB) is in

the feedback loop, not the battery. The constant-current

mode stability is affected by the impedance at the charge

current program pin. With no additional capacitance on

this pin, the charger is stable with program resistor val-

ues as high as 20k (I

capacitance on these nodes reduces the maximum allowed

program resistor value.

Checking Regulator Transient Response

The regulator loop response can be checked by looking

at the load transient response. Switching regulators take

several cycles to respond to a step in load current. When

a load step occurs, V

equal to (ΔI

resistance of C

charge C

regulator loop then acts to return V

value. During this recovery time V

APPLICATIO S I FOR ATIO

BAT

OUT

105

LOAD

, which generates a feedback error signal. The

OUT

C T

(

• ESR), where ESR is the effective series

–

. ΔI

OUT

–

CHG

LOAD

−

immediately shifts by an amount

double sided 1oz copper board,

BAT

(

= 50mA); however, additional

D BUCK

also begins to charge or dis-

(

)

•

)

OUT

•

can be monitored

to its steady state

)

(7)

for overshoot or ringing that would indicate a stability

problem. For a detailed explanation of switching control

loop theory, see Application Note 76.

A second, more severe transient is caused by switching

in loads with large (>1µF) supply bypass capacitors. The

discharged bypass capacitors are effectively put in paral-

lel with C

can deliver enough current to prevent this problem if the

load switch resistance is low and it is driven quickly. The

only solution is to limit the rise time of the switch drive

so that the load rise time is limited to approximately (25

• C

require a 250µs rise time, limiting the charging current

to about 130mA.

Protecting the USB Pin and Wall Adapter Input from

Overvoltage Transients

Caution must be exercised when using ceramic capaci-

tors to bypass the USBIN pin or the wall adapter inputs.

High voltage transients can be generated when the USB

or wall adapter is hot-plugged. When power is supplied

via the USB bus or wall adapter, the cable inductance

along with the self resonant and high Q characteristics of

ceramic capacitors can cause substantial ringing which

could exceed the maximum voltage ratings and damage

the LTC3550-1. Refer to Linear Technology Application

Note 88, entitled “Ceramic Input Capacitors Can Cause

Overvoltage Transients” for a detailed discussion of this

problem. The long cable lengths of most wall adapters

and USB cables makes them especially susceptible to this

problem. To bypass the USB and the wall adapter inputs,

add a 1Ω resistor in series with a ceramic capacitor to

lower the effective Q of the network and greatly reduce the

ringing. A tantalum, OS-CON, or electrolytic capacitor can

be used in place of the ceramic and resistor, as their higher

ESR reduces the Q, thus reducing the voltage ringing.

The oscilloscope photograph in Figure 4 shows how seri-

ous the overvoltage transient can be for the USB and wall

adapter inputs. For both traces, a 5V supply is hot-plugged

using a three foot long cable. For the top trace, only a

4.7µF ceramic X5R capacitor (without the recommended

1Ω series resistor) is used to locally bypass the input.

This trace shows excessive ringing when the 5V cable

is inserted, with the overvoltage spike reaching 10V. For

LOAD

). Thus, a 10µF capacitor charging to 3.3V would

OUT

, causing a rapid drop in V

LTC3550-1

OUT

. No regulator

35501f

LTC3550EDHC-1#TR Linear Technology, LTC3550EDHC-1#TR Datasheet - Page 19

LTC3550EDHC-1#TR

Specifications of LTC3550EDHC-1#TR

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