MAX15022 Datasheet, PDF(15/27 Page) Maxim Integrated Products – Dual, 4A/2A, 4MHz, Step-Down DC-DC Regulator with Dual LDO Controllers

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MAX15022 Datasheet, PDF (15/27 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

Effective Input-Voltage Range

Although the MAX15022âs regulators can operate from

input supplies ranging from 2.5V to 5.5V, the input-volt-

age range can be effectively limited by the

MAX15022âs duty-cycle limitations for a given output

voltage (VOUT_). The maximum input voltage

(VPVIN_MAX) can be effectively limited by the control-

lable minimum on-time (tON(MIN)):

VPVIN_MAX[V] â¤

VOUT_ [V]

tON(MIN)[Î¼s]Ã fSW

[MHz]

where tON(MIN) is 0.06Î¼s (typ).

The minimum input voltage (VPVIN_MIN) can be effec-

tively limited by the maximum controllable duty cycle

and is calculated using the following equation:

VPVIN_MIN[V]

â¥

1â

VOUT_ [V]

(tOFF(MIN)[Î¼s]Ã fSW

[MHz])

where VOUT_ is the regulator output voltage and

tOFF(MIN) is the 0.06Î¼s (typ) controllable off-time.

Inductor Selection

Three key inductor parameters must be specified for

operation with the MAX15022: inductance value (L),

peak inductor current (IPEAK), and inductor saturation

current (ISAT). The minimum required inductance is a

function of operating frequency, input-to-output voltage

differential, and the peak-to-peak inductor current

(ÎIP-P). Higher ÎIP-P allows for a lower inductor value. A

lower inductance minimizes size and cost and

improves large-signal and transient response.

However, efficiency is reduced due to higher peak cur-

rents and higher peak-to-peak output-voltage ripple for

the same output capacitor. A higher inductance

increases efficiency by reducing the ripple current;

however, resistive losses due to extra wire turns can

exceed the benefit gained from lower ripple current lev-

els especially when the inductance is increased without

also allowing for larger inductor dimensions. Choose

the inductorâs peak-to-peak current, ÎIP-P, in the range

of 20% to 50% of the full load current; as a rule of

thumb 30% is typical.

Calculate the inductance, L, using the following equation:

L[Î¼H] = VOUT_ [V]Ã (VPVIN_ [V]â VOUT_ [V])

VPVIN_ [V]Ã fSW [MHz]Ã ÎIPâP [A]

where VPVIN_ is the input supply voltage, VOUT_ is the

regulator output voltage, and fSW is the switching fre-

quency. Use typical values for VPVIN_ and VOUT_ so

that efficiency is optimum for typical conditions. The

switching frequency (fSW) is programmable between

500kHz and 4MHz (see the Oscillator section).

The peak-to-peak inductor current (ÎIP-P), which

reflects the peak-to-peak output ripple, is largest at the

maximum input voltage. See the Output-Capacitor

Selection section to verify that the worst-case output

current ripple is acceptable.

Select an inductor with a saturation current, ISAT, high-

er than the maximum peak current to avoid runaway

current during continuous output short-circuit condi-

tions. Also, confirm that the inductorâs thermal perfor-

mances and projected temperature rise above ambient

does not exceed its thermal capacity. Many inductor

manufacturers provide bias/load current versus tem-

perature rise performance curves (or similar) to obtain

this information.

Input-Capacitor Selection

The discontinuous input current of the buck converter

causes large input ripple currents and therefore the

input capacitor must be carefully chosen to withstand

the input ripple current and keep the input-voltage rip-

ple within design requirements.

The input-voltage ripple is comprised of ÎVQ (caused

by the capacitor discharge) and ÎVESR (caused by the

ESR of the input capacitor). The total voltage ripple is

the sum of ÎVQ and ÎVESR which peaks at the end of

the on-cycle. Calculate the required input capacitance

and ESR for a specified ripple using the following equa-

tions:

ESR[mÎ©] =

ÎVESR[mV]

âââILOAD(MAX)

ÎIPâP

ââ â[A]

CPVIN_ [Î¼F]

ILOAD(MAX)[A]

ââ

VOUT_[V] â

VPVIN_ [V] â â

ÎVQ[V] Ã fSW[MHz]

( ) ÎIPâP[A] =

VPVIN_ â VOUT_ [V] Ã VOUT_[V]

VPVIN_[V] Ã fSW[MHz] Ã L[Î¼H]

ILOAD(MAX) is the maximum output current, ÎIP-P is the

peak-to-peak inductor current, and VPVIN_ is the input

supply voltage, VOUT_ is the regulator output voltage,

and fSW is the switching frequency.

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