MAX1637 Datasheet, PDF(11/20 Page) Maxim Integrated Products – Miniature, Low-Voltage, Precision Step-Down Controller

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MAX1637 Datasheet, PDF (11/20 Pages) Maxim Integrated Products – Miniature, Low-Voltage, Precision Step-Down Controller

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Miniature, Low-Voltage,

Precision Step-Down Controller

Idle Mode

When SKIP is low, idle-mode circuitry automatically

optimizes efficiency throughout the load-current range.

Idle mode dramatically improves light-load efficiency

by reducing the effective frequency, subsequently

reducing switching losses. It forces the peak inductor

current to ramp to 30% of the full current limit, deliver-

ing extra energy to the output and allowing subsequent

cycles to be skipped. Idle mode transitions seamlessly

to fixed-frequency PWM operation as load current

increases (Table 3).

Fixed-Frequency Mode

When SKIP is high, the controller always operates in

fixed-frequency PWM mode for lowest noise. Each pulse

from the oscillator sets the main PWM latch that turns on

the high-side switch for a period determined by the duty

factor (approximately VOUT / VIN). As the high-side switch

turns off, the synchronous rectifier latch is set; 60ns later,

the low-side switch turns on. The low-side switch stays on

until the beginning of the next clock cycle.

In PWM mode, the controller operates as a fixed-fre-

quency, current-mode controller in which the duty fac-

tor is set by the input/output voltage ratio. PWM mode

(SKIP = high) forces two changes on the PWM con-

troller. First, it disables the minimum-current compara-

tor, ensuring fixed-frequency operation. Second, it

changes the detection threshold for reverse-current

limit from 0mV to -100mV, allowing the inductor current

to reverse at light loads. This results in fixed-frequency

operation and continuous inductor-current flow. PWM

mode eliminates discontinuous-mode inductor ringing

and improves cross-regulation of transformer-coupled,

multiple-output supplies.

Table 3. SKIP PWM Table

SKIP

LOAD

CURRENT

MODE

DESCRIPTION

Low

Light

Idle

Pulse-skipping, discontin-

uous inductor current

Low

Heavy

PWM

Constant frequency PWM,

continuous inductor current

High

Light

PWM

Constant frequency PWM,

continuous inductor current

High

Heavy

PWM

Constant frequency PWM,

continuous inductor current

The current-mode feedback system regulates the peak

inductor-current value as a function of the output volt-

age error signal. In continuous-conduction mode, the

average inductor current is nearly the same as the

peak current, so the circuit acts as a switch-mode

transconductance amplifier. This pushes the second

output LC filter pole, normally found in a duty-factor-

controlled (voltage-mode) PWM, to a higher frequency.

To preserve inner-loop stability and eliminate regenera-

tive inductor-current âstaircasing,â a slope-compensa-

tion ramp is summed into the main PWM comparator to

make the apparent duty factor less than 50%.

The relative gains of the voltage-sense and current-

sense inputs are weighted by the values of the current

sources that bias four differential input stages in the

main PWM comparator (Figure 4). The voltage sense

into the PWM has been conditioned by an integrated

component of the feedback voltage, yielding excellent

DC output voltage accuracy. See the Output Voltage

Accuracy section for details.

VCC

TO PWM

LOGIC

UNCOMPENSATED

HIGH-SPEED

LEVEL TRANSLATOR

AND BUFFER

OUTPUT DRIVER

VBIAS

REF

CSH

CSL

SLOPE COMPENSATION

Figure 4. Main PWM Comparator Functional Diagram

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