MAX1954AEUB-T Maxim Integrated Products, MAX1954AEUB-T Datasheet - Page 14

MAX1954AEUB-T

Manufacturer Part Number

MAX1954AEUB-T

Description

Current Mode PWM Controllers

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1954AEUB-G05.pdf (18 pages)

Specifications of MAX1954AEUB-T

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

Current page: 14 of 18
Download datasheet (350Kb)

where V

frequency. Choose a R

the specific application’s derating rule for the power

dissipation calculated.

The input filter capacitor reduces peak currents drawn

from the power source and reduces noise and voltage

ripple on the input caused by the circuit’s switching.

The input capacitor must meet the ripple current

requirement (I

defined by the following equation:

equals twice the output voltage (V

fore, I

recommended due to their low equivalent series resis-

tance (ESR) and equivalent series inductance (ESL) at

high frequencies, and their relatively low cost. Choose

a capacitor that exhibits less than 10 C temperature

rise at the maximum operating root-mean-square (RMS)

current for optimum long-term reliability.

The key selection parameters for the output capacitor

are the actual capacitance value, ESR, ESL, and the

voltage-rating requirements. These parameters affect

the overall stability, output voltage ripple, and transient

response. The output ripple has three components: vari-

ations in the charge stored in the output capacitor, and

the voltage drop across the capacitor’s ESR and ESL

caused by the current into and out of the capacitor. The

equation below estimates the maximum ripple voltage:

The output voltage ripple as a consequence of the ESR,

output capacitance, and ESL are as follows:

Low-Cost, Current-Mode PWM Buck

Controller with Foldback Current Limit

RMS

RIPPLE

______________________________________________________________________________________

has a maximum value when the input voltage

RMS

RMS(MAX)

P P

RIPPLE ESR

RIPPLE C

RIPPLE ESL

is the input voltage and f

RMS

RIPPLE ESR

LOAD

= I

( )

(

) imposed by the switching currents

LOAD

(

)

SNUB

)

/ 2. Ceramic capacitors are

P P

OUT

RIPPLE C

power rating that meets

P P

OUT

Output Capacitor

ESR

Input Capacitor

( )

ESL

= 2 x V

is the switching

OUT

RIPPLE ESL

OUT

); there-

(

)

where I

Inductor Value section). These equations are suitable

for initial capacitor selection, but final values should be

chosen based on a prototype or evaluation circuit. As a

general rule, a smaller current ripple results in less out-

put voltage ripple. Since the inductor ripple current is a

factor of the inductor value and input voltage, the out-

put voltage ripple decreases with larger inductance,

and increases with higher input voltages. For the

MAX1954A polymer, tantalum, or aluminum electrolytic

capacitors are recommended. Lower-cost aluminum

electrolytic capacitors with relatively low ESR are avail-

able and can be used for the MAX1954A, if the larger

physical size is acceptable. For reliable and safe oper-

ation, ensure that the capacitor’s voltage and ripple-

current ratings exceed the calculated values.

The devices’ response to a load transient depends on

the selected output capacitors. After a load transient,

the output voltage instantly changes by ESR x I

Before the controller can respond, the output voltage

deviates further depending on the inductor and output

capacitor values. After a short period of time (see the

Typical Operating Characteristics), the controller

responds by regulating the output voltage back to its

nominal state. The controller response time depends on

its closed-loop bandwidth. With a higher bandwidth, the

response time is faster, thus preventing the output volt-

age from deviating further from its regulation value.

The MAX1954A uses an internal transconductance

error amplifier whose output compensates the control

loop. The external inductor, high-side MOSFET, output

capacitor, compensation resistor, and compensation

capacitors determine the loop stability. The inductor

and output capacitors are chosen based on perfor-

mance, size, and cost. Additionally, the compensation

resistor and capacitors are selected to optimize control-

loop stability. The component values in Figures 1 and 2

yield stable operation over the given range of input-to-

output voltages and load currents. The controller uses a

current-mode control scheme that regulates the output

voltage by forcing the required current through the

external inductor. The MAX1954A uses the voltage

across the high-side MOSFET’s on-resistance

control eliminates the double pole in the feedback loop

caused by the inductor and output capacitor, resulting

in a smaller phase shift and requiring less elaborate

error-amplifier compensation. A single-series compen-

sation resistor (R

all that is needed to have a stable high-bandwidth loop

in applications where ceramic capacitors are used for

DS(ON)

P-P

) to sense the inductor current. Current-mode

is the peak-to-peak inductor current (see the

) and compensation capacitor (C

Compensation Design

LOAD

) is

MAX1954AEUB-T Maxim Integrated Products, MAX1954AEUB-T Datasheet - Page 14

MAX1954AEUB-T

Specifications of MAX1954AEUB-T

Related parts for MAX1954AEUB-T