MAX1524EUT+T Maxim Integrated Products, MAX1524EUT+T Datasheet - Page 10

MAX1524EUT+T

Manufacturer Part Number

MAX1524EUT+T

Description

IC SIMPLE BOOST CNTRLR SOT23-6

Manufacturer

Maxim Integrated Products

Type

Step-Up (Boost), Flyback, Sepicr

Datasheet

1.MAX1524EUT-T.pdf (14 pages)

Specifications of MAX1524EUT+T

Internal Switch(s)

Synchronous Rectifier

Number Of Outputs

Voltage - Output

2.5 ~ 5 V

Frequency - Switching

1MHz

Voltage - Input

1.5 ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

SOT-23-6

Power - Output

696mW

Output Voltage

2.5 V to 5 V

Output Current

0.95 A

Input Voltage

1.5 V to 5.5 V

Mounting Style

SMD/SMT

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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Simple SOT23 Boost Controllers

For proper control of peak inductor current during soft-

start and for stable switching, the ripple at FB should

be greater than 25mV. Without a feed-forward capaci-

tor connected between the output and FB, the output’s

ripple must be at least 2% of V

requirement. Alternatively, if a low-ESR output capacitor

is chosen to obtain small output ripple, then a feed-for-

ward capacitor should be used, and the output ripple

may be as low as 25mV. The approximate value of the

feed-forward capacitor is given by:

Do not use a feed-forward capacitor that is much larger

than this because line-transient performance will

degrade. Do not use a feed-forward capacitor at all if

the output ripple is large enough without it to provide

stable switching because load regulation will degrade.

When using a feed-forward capacitor, it is possible to

achieve too much ripple at FB. The symptoms of this

include excessive line and load regulation and possibly

high output ripple at light loads in the form of pulse

groupings or “bursts.” Fortunately, this is easy to cor-

rect by either choosing a lower-ESR output capacitor or

by adding a feedback capacitor between FB and

ground. This feedback capacitor (C

feed-forward capacitor, form an AC-coupled ripple volt-

age-divider from the output to FB:

It is relatively simple to determine a good value for C

experimentally. Start with C

in half; then increase or decrease C

ideal ripple at FB is from 25mV to 40mV, which will pro-

vide stable switching, low output ripple at light and

medium loads, and reasonable line and load regula-

tion. Never use a feedback capacitor without also using

a feed-forward capacitor.

The input capacitor (C

current peaks drawn from the input supply, increases

efficiency, and reduces noise injection. The source

impedance of the input supply largely determines the

value of C

input capacitance, particularly as the input voltage

______________________________________________________________________________________

Optional Feedback Capacitor Selection

Ripple

. High source impedance requires high

≅ ×

Ripple

3 10

Input Capacitor Selection

) in boost designs reduces the

−

OUTPUT

Optional Feed-Forward

⎛

⎜

⎝

Capacitor Selection

= C

OUT

⎛

⎜

⎝

in order to meet this

⎞

⎟

⎠

to cut the FB ripple

)

as needed. The

along with the

⎞

⎟

⎠

falls. Since step-up DC-DC converters act as “constant-

power” loads to their input supply, input current rises

as input voltage falls. Consequently, in low-input-volt-

age designs, increasing C

can add as many as five percentage points to conver-

sion efficiency. A good starting point is to use the same

capacitance value for C

capacitor must also meet the ripple current requirement

imposed by the switching currents, which is about 30%

of I

designs.

In addition to the bulk input capacitor, a ceramic 0.1µF

bypass capacitor at V

tor should be located as close to V

sible. In bootstrapped configuration, it is recommended

to isolate the bypass capacitor from the output capaci-

tor with a series 10Ω resistor between the output and

The MAX1522/MAX1523/MAX1524 drive a wide variety

of N-channel power MOSFETs (NFETs). Since the out-

put gate drive is limited to V

required. Best performance, especially when V

less than 4.5V, is achieved with low-threshold NFETs

that specify on-resistance with a gate-source voltage

parameters include:

1) Total gate charge (Qg)

2) Reverse transfer capacitance or charge (C

3) On-resistance (R

4) Maximum drain-to-source voltage (V

5) Minimum threshold voltage (V

At high switching rates, dynamic characteristics (para-

meters 1 and 2 above) that predict switching losses

may have more impact on efficiency than R

which predicts I

associated with charging the gate. In addition, this

parameter helps predict the current needed to drive the

gate when switching at high frequency. The continuous

Use the FET manufacturer’s typical value for Qg (see

manufacturer’s graph of Qg vs. Vgs) in the above

equation since a maximum value (if supplied) is usually

too conservative to be of any use in estimating I

PEAK

current due to gate drive is:

) of 2.7V or less. When selecting an NFET, key

in CCM designs and 100% of I

R losses. Qg includes all capacitances

GATE

DS(ON)

Power MOSFET Selection

is recommended. This capaci-

)

× ƒ

as for C

SWITCHING

and/or lowering its ESR

, a logic-level NFET is

TH(MIN)

and GND as pos-

OUT

DS(MAX)

)

PEAK

. The input

RSS

GATE

DS(ON)

in DCM

)

MAX1524EUT+T Maxim Integrated Products, MAX1524EUT+T Datasheet - Page 10

MAX1524EUT+T

Specifications of MAX1524EUT+T

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