MAX16904_13 Datasheet, PDF(9/15 Page) Maxim Integrated Products – 2.1MHz, High-Voltage, 600mA Mini-Buck Converter

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

MAX16904_13 Datasheet, PDF (9/15 Pages) Maxim Integrated Products – 2.1MHz, High-Voltage, 600mA Mini-Buck Converter

◁

MAX16904

2.1MHz, High-Voltage,

600mA Mini-Buck Converter

Detailed Description

The MAX16904 is a small, current-mode buck converter

that features synchronous rectification and requires no

external compensation network. The device is designed

for 600mA output current, and can stay in dropout by

running at 97% duty cycle. It provides an accurate out-

put voltage within the +6.5V to +18V input range.

Voltage quality can be monitored by observing the

PGOOD signal. The device operates at 2.1MHz (typ)

frequency, which allows for small external components,

reduced output ripple, and guarantees no AM band

interference.

The device features an ultra-low 25Î¼A (typ) quiescent

supply current in standby mode. Standby mode is

entered when load currents are below 5mA and when

SYNC is low. The device operates from a +3.5V to

+28V supply voltage and tolerates transients up to

+42V, making it ideal for automotive applications. The

device is available in factory-trimmed output voltages

from 1.8V to 10.7V in 100mV steps. Contact the factory

for availability of voltage options.

Enable (EN)

The device is activated by driving EN high. EN is com-

patible from a +3.3V logic level to automotive battery

levels. EN can be controlled by microcontrollers and

automotive KEY or CAN inhibit signals. The EN input

has no internal pullup/pulldown current to minimize

overall quiescent supply current. To realize a program-

mable undervoltage lockout level, use a resistor-

divider from SUP to EN to GND.

BIAS/UVLO

The device features undervoltage lockout. When the

device is enabled, an internal bias generator turns on.

LX begins switching after VBIAS has exceeded the inter-

nal undervoltage lockout level VUVLO = 3V (typ).

Soft-Start

The device features an internal soft-start timer. The out-

put voltage soft-start ramp time is 8ms (typ). If a short

circuit or undervoltage is encountered, after the soft-

start timer has expired, the device is disabled for 30ms

(typ) and it reattempts soft-start again. This pattern

repeats until the short circuit has been removed.

Oscillator/Synchronization and

Efficiency (SYNC)

The device has an on-chip oscillator that provides a

switching frequency of 2.1MHz (typ). Depending on the

condition of SYNC, two operation modes exist. If SYNC

is unconnected or at GND, the device must operate in

highly efficient pulse-skipping mode if the load current

is below the SKIP mode current threshold. If SYNC is at

Maxim Integrated

BIAS or has a frequency applied to it, the device is in

forced PWM mode. The device offers the best of both

worlds. The device can be switched during operation

between forced PWM mode and SKIP mode by switch-

ing SYNC.

SKIP Mode Operation

SKIP mode is entered when the SYNC pin is connected

to ground or is unconnected and the peak load current

is < 350mA (typ). In this mode, the high-side FET is

turned on until the current in the inductor is ramped up

to 350mA (typ) peak value and the internal feedback

voltage is above the regulation voltage (1.2V typ). At

this point, both the high-side and low-side FETs are

turned off. Depending on the choice of the output

capacitor and the load current the high-side FET turns

on when OUTS (valley) drops below the 1.2V (typ) feed-

back voltage.

Achieving High Efficiency at Light Loads

The device operates with very low quiescent current at

light loads to enhance efficiency and conserve battery

life. When the device enters SKIP mode the output cur-

rent is monitored to adjust the quiescent current.

When the output current is < 5mA, the device operates in

the lowest quiescent current mode also called the stand-

by mode. In this mode, the majority of the internal circuit-

ry (excluding that necessary to maintain regulation) in the

device, including the internal high-voltage LDO, is turned

off to save current. Under no load and with SKIP mode

enabled, the device draws only 25Î¼A (typ) current. For

load currents > 5mA, the device enters normal SKIP

mode while still maintaining very high efficiency.

Controlled EMI with Forced-Fixed Frequency

In forced PWM mode, the device attempts to operate at

a constant switching frequency for all load currents. For

tightest frequency control, apply the operating frequen-

cy to SYNC. The advantage of this mode is a constant

switching frequency, which improves EMI performance;

the disadvantage is that considerable current can be

thrown away. If the load current during a switching

cycle is less than the current flowing through the induc-

tor, the excess current is diverted to GND. With no

external load present, the operating current is in the

10mA range.

Extended Input Voltage Range

In some cases, the device is forced to deviate from its

operating frequency independent of the state of SYNC.

For input voltages above 18V, the required duty cycle

to regulate its output may be smaller than the minimum

on-time (80ns, typ). In this event, the device is forced to

lower its switching frequency by skipping pulses.

▷