MAX1954AEUB Maxim Integrated Products, MAX1954AEUB Datasheet - Page 12

MAX1954AEUB

Manufacturer Part Number

MAX1954AEUB

Description

Current Mode PWM Controllers

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1954AEUB-G05.pdf (18 pages)

Specifications of MAX1954AEUB

Number Of Outputs

Duty Cycle (max)

93 %

Output Voltage

0.8 V to 4.95 V

Output Current

25000 mA

Mounting Style

SMD/SMT

Package / Case

uSOP-10

Switching Frequency

360 KHz

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Synchronous Pin

Topology

Boost, Buck

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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Current page: 12 of 18
Download datasheet (350Kb)

The MAX1954A features a low-power shutdown mode.

Use an open-collector, NPN transistor to pull COMP low

and shut down the IC. COMP must be pulled below

0.25V to shut down the MAX1954A. Choose a transistor

with a V

put is high impedance. Shutdown reduces the quies-

cent current (I

shutdown in this fashion discharges the output only

until the inductor runs out of energy. Upon recovery,

soft-start is not available. Only the foldback current limit

results in pseudo-soft-start mode.

Thermal-overload protection limits total power dissipa-

tion in the MAX1954A. When the junction temperature

exceeds T

down the IC, allowing the IC to cool. The thermal sensor

turns the IC on again after the junction temperature

cools by 15 C, resulting in a pulsed output during con-

tinuous thermal-overload conditions.

To set the output voltage for the MAX1954A, connect

FB to the center of an external resistor-divider from the

output to GND (Figures 1 and 2). Select R2 between

8k and 24k , and calculate R1 by:

where V

close as possible to the IC.

There are several parameters that must be examined

when determining which inductor to use. Input voltage,

output voltage, load current, switching frequency, and

LIR. LIR is the ratio of inductor current ripple to DC load

current. A higher LIR value allows for a smaller induc-

tor, but results in higher losses and higher output rip-

ple. A good compromise between size and efficiency is

an LIR of 30%. Once all of the parameters are chosen,

the inductor value is determined as follows:

where f

value close to the calculated value. The exact inductor

value is not critical and can be adjusted to make trade-

offs among size, cost, and efficiency. Lower inductor val-

Low-Cost, Current-Mode PWM Buck

Controller with Foldback Current Limit

______________________________________________________________________________________

CE(SAT)

is the switching frequency. Choose a standard

= 0.8V. R1 and R2 should be placed as

= +160 C, an internal thermal sensor shuts

) to 220µA (typ). Note that implementing

below 0.25V. During shutdown, the out-

Thermal-Overload Protection

OUT

Setting the Output Voltage

Design Procedures

LOAD MAX

OUT

Inductor Value

LIR

Shutdown

ues minimize size and cost, but they also increase the

output ripple and reduce the efficiency due to higher

peak currents. On the other hand, higher inductor values

increase efficiency, but eventually resistive losses, due to

extra turns of wire, exceed the benefit gained from lower

AC levels. Find a low-loss inductor with the lowest possi-

ble DC resistance that fits the allotted dimensions. Ferrite

cores are often the best choice. However, powdered iron

is inexpensive and can work well at 300kHz. The chosen

inductor’s saturation current rating must exceed the peak

inductor current determined as:

The MAX1954A uses a valley current-sense method for

current limiting. The voltage drop across the low-side

MOSFET due to its on-resistance is used to sense the

inductor current. The voltage drop across the low-side

MOSFET at the valley point and at I

The calculated V

current-limit threshold specified.

Additionally, the high-side MOSFET R

the following equation to avoid tripping the internal

peak-current clamp circuit prematurely:

Use the maximum R

mum operating junction temperature of the MOSFET. A

good general rule is to allow 0.5% additional resistance

for each C of MOSFET junction-temperature rise.

The MAX1954A drives two external, logic-level, N-chan-

nel MOSFETs as the circuit-switch elements. The key

selection parameters are:

1) On-resistance (R

2) Maximum drain-to-source voltage (V

3) Gate charges (Q

For a 3.3V input application, choose a MOSFET with a

rated R

choose the MOSFETs with rated R

For a good compromise between efficiency and cost,

VALLEY

DS(ON)

However, the current-sense signal (R

must be greater than 16mV at maximum load.

be at least 20% higher than the input supply rail at

the high-side MOSFET’s drain.

DS(ON)

PEAK

< 0.8V / (3.65 x (I

DS ON

at V

(

LOAD MAX

VALLEY

)

DS(ON)

, Q

= 2.5V. For a 5V input application,

(

DS(ON)

Setting the Current Limit

LOAD MAX

must be less than the minimum

, Q

LOAD(MAX)

(

value at the desired maxi-

): the lower, the better.

LIR

MOSFET Selection

): the lower, the better.

)

DS(ON)

LOAD(MAX)

LIR

DS(ON)

LOAD MAX

x ( 1 + LIR / 2)))

DSS

at V

LOAD MAX

): it should

must meet

is:

x I

PEAK

4.5V.

)

MAX1954AEUB Maxim Integrated Products, MAX1954AEUB Datasheet - Page 12

MAX1954AEUB

Specifications of MAX1954AEUB

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