MAX15022 Datasheet, PDF(16/27 Page) Maxim Integrated Products – Dual, 4A/2A, 4MHz, Step-Down DC-DC Regulator with Dual LDO Controllers

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MAX15022 Datasheet, PDF (16/27 Pages) Maxim Integrated Products – Dual, 4A/2A, 4MHz, Step-Down DC-DC Regulator with Dual LDO Controllers

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Dual, 4A/2A, 4MHz, Step-Down DC-DC

Regulator with Dual LDO Controllers

Use the following equation to calculate the input ripple

when only one regulator is enabled:

ICIN(RMS)[A] = ILOAD(MAX)[A] Ã

( ) VOUT_[V] Ã VPVIN_ â VOUT_ [V]

VPVIN_ [V]

The MAX15022 includes UVLO hysteresis to avoid possi-

ble unintentional chattering during turn-on. Use additional

bulk capacitance if the input source impedance is high. If

using a lower input voltage, additional input capacitance

helps to avoid possible undershoot below the undervolt-

age lockout threshold during transient loading.

Output-Capacitor Selection

The allowed output-voltage ripple and the maximum

deviation of the output voltage during load steps deter-

mine the required output capacitance and its ESR. The

output ripple is mainly composed of ÎVQ (caused by

the capacitor discharge) and ÎVESR (caused by the

voltage drop across the equivalent series resistance of

the output capacitor). The equations for calculating the

output capacitance and its ESR are:

COUT [Î¼F]

8Ã

ÎIPâP [A]

ÎVQ[V]Ã fSW

[MHz]

ESR[mÎ©] = 2 Ã ÎVESR [mV]

ÎIPâP [A]

where ÎIP-P is the peak-to-peak inductor current, and

fSW is the switching frequency.

ÎVESR and ÎVQ are not directly additive since they are

out of phase from each other. If using ceramic capaci-

tors, which generally have low ESR, ÎVQ dominates. If

using electrolytic capacitors, ÎVESR dominates.

The allowable deviation of the output voltage during

fast load transients also affects the output capacitance,

its ESR, and its equivalent series inductance (ESL). The

output capacitor supplies the load current during a

load step until the controller responds with an

increased duty cycle. The response time (tRESPONSE)

depends on the gain bandwidth of the controller (see

the Compensation-Design Guidelines section). The

resistive drop across the output capacitorâs ESR

(ÎVESR), the drop across the capacitorâs ESL (ÎVESL),

and the capacitor discharge (ÎVQ) causes a voltage

droop during the load-step (ISTEP). Use a combination

of low-ESR tantalum/aluminum electrolyte and ceramic

capacitors for better load transient and voltage ripple

performance. Non-leaded capacitors and capacitors in

parallel help reduce the ESL. Keep the maximum out-

put-voltage deviation below the tolerable limits of the

electronics being powered.

Use the following equations to calculate the required

output capacitance, ESR, and ESL for minimal output

deviation during a load step:

ESR[mÎ©] = ÎVESR [mV]

ISTEP [A]

COUT

[Î¼F]

ISTEP

[A]

Ã tRESPONSE

ÎVQ [V]

[Î¼s]

ESL[nH] = ÎVESL[mV]Ã tSTEP[Î¼s]

ISTEP [A]

where ISTEP is the load step, tSTEP is the rise time of the

load step, and tRESPONSE is the response time of the

controller.

Compensation Design Guidelines

The MAX15022 uses a fixed-frequency, voltage-mode

control scheme that regulates the output voltage by

comparing the output voltage against a fixed reference.

The subsequent âerrorâ voltage that appears at the

error-amplifier output (COMP_) is compared against an

internal ramp voltage to generate the required duty

cycle of the PWM. A second order lowpass LC filter

removes the switching harmonics and passes the DC

component of the PWM signal to the output. The LC fil-

ter has an attenuation slope of -40dB/decade and intro-

duces 180Â° of phase shift at frequencies above the LC

resonant frequency. This phase shift in addition to the

inherent 180Â° of phase shift of the regulatorâs negative

feedback system turns the feedback into unstable posi-

tive feedback. The error amplifier and its associated

circuitry must be designed to achieve a stable closed-

loop system.

The basic controller loop consists of a power modulator

(comprised of the regulatorâs PWM, associated circuitry,

and LC filter), an output feedback divider, and an error

amplifier. The power modulator has a DC gain set by

VAVIN/VRAMP where the ramp voltage (VRAMP) is a func-

tion of the VAVIN and results in a fixed DC gain of 4V/V,

providing effective feed-forward compensation of input-

voltage supply DC variations. The feed-forward com-

pensation eliminates the dependency of the power mod-

ulatorâs gain on the input voltage such that the feedback

compensation of the error amplifier requires no modifi-

cations for nominal input-voltage changes. The output

filter is effectively modeled as a double-pole and a sin-

gle zero set by the output inductance (L), the DC resis-

tance of the inductor (DCR), the output capacitance

(COUT), and its equivalent series resistance (ESR).

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