MAX1631AEAI Maxim Integrated Products, MAX1631AEAI Datasheet - Page 18

MAX1631AEAI

Manufacturer Part Number

MAX1631AEAI

Description

DC/DC Switching Controllers

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1634CAI.pdf (29 pages)

Specifications of MAX1631AEAI

Number Of Outputs

Output Voltage

2.5 V to 5.5 V, 3.3 V, 5 V

Output Current

1 A

Input Voltage

4.2 V to 30 V

Mounting Style

SMD/SMT

Package / Case

SSOP-28

Maximum Operating Temperature

+ 85 C

Minimum Operating Temperature

- 40 C

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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sistor can be added. Figure 6’s circuit delivers more

than 200mA. Total output current is constrained by the

V+ input voltage and the transformer primary load (see

Maximum 15V V

graphs in the Typical Operating Characteristics).

The three predesigned 3V/5V standard application cir-

cuits (Figure 1 and Table 1) contain ready-to-use solu-

tions for common application needs. Also, two standard

flyback transformer circuits support the 12OUT linear

regulator in the Applications Information section. Use

the following design procedure to optimize these basic

schematics for different voltage or current require-

ments. But before beginning a design, firmly establish

the following:

Maximum input (battery) voltage, V

value should include the worst-case conditions, such

as no-load operation when a battery charger or AC

adapter is connected but no battery is installed.

Minimum input (battery) voltage, V

should be taken at full load under the lowest battery

conditions. If V

circuit to externally hold VL above the VL undervoltage

lockout threshold. If the minimum input-output differ-

ence is less than 1.5V, the filter capacitance required to

maintain good AC load regulation increases (see Low-

Voltage Operation section).

The exact inductor value isn’t critical and can be freely

adjusted to make trade-offs between size, cost, and

efficiency. Lower inductor values minimize size and

cost, but reduce efficiency due to higher peak-current

levels. The smallest inductor is achieved by lowering

the inductance until the circuit operates at the border

between continuous and discontinuous mode. Further

reducing the inductor value below this crossover point

results in discontinuous-conduction operation even at

full load. This helps lower output filter capacitance

requirements, but efficiency suffers due to high I

losses. On the other hand, higher inductor values mean

greater efficiency, but resistive losses due to extra wire

turns will eventually exceed the benefit gained from

lower peak-current levels. Also, high inductor values

can affect load-transient response (see the V

tion in the Low-Voltage Operation section). The equa-

tions that follow are for continuous-conduction

operation, since the MAX1630 family is intended mainly

Multi-Output, Low-Noise Power-Supply

Controllers for Notebook Computers

__________________Design Procedure

IN(MAX)

______________________________________________________________________________________

must not exceed 30V.

IN(MIN)

Output Current vs. Supply Voltage

is less than 4.2V, use an external

Inductor Value

IN(MAX)

IN(MIN)

SAG

. This

equa-

for high-efficiency, battery-powered applications. See

Appendix A in Maxim’s Battery Management and DC-

DC Converter Circuit Collection for crossover-point and

discontinuous-mode equations. Discontinuous conduc-

tion doesn’t affect normal Idle Mode operation.

Three key inductor parameters must be specified:

inductance value (L), peak current (I

resistance (R

constant, LIR, which is the ratio of inductor peak-to-

peak AC current to DC load current. A higher LIR value

allows smaller inductance, but results in higher losses

and higher ripple. A good compromise between size

and losses is found at a 30% ripple-current to load-

current ratio (LIR = 0.3), which corresponds to a peak

inductor current 1.15 times higher than the DC load

current.

where: f = switching frequency, normally 200kHz or

The nominal peak inductor current at full load is 1.15 x

current can be calculated by:

The inductor’s DC resistance should be low enough that

ciency performance. If a standard off-the-shelf inductor

is not available, choose a core with an LI

than L x I

wire that fits the winding area. For 300kHz applications,

ferrite core material is strongly preferred; for 200kHz

applications, Kool-Mu

dered iron is acceptable. If light-load efficiency is unim-

portant (in desktop PC applications, for example), then

low-permeability iron-powder cores, such as the

Micrometals type found in Pulse Engineering’s 2.1µH

PE-53680, may be acceptable even at 300kHz. For

high-current applications, shielded-core geometries,

such as toroidal or pot core, help keep noise, EMI, and

switching-waveform jitter low.

Kool-Mu is a registered trademark of Magnetics Div., Spang & Co.

OUT

x I

if the above equation is used; otherwise, the peak

PEAK

LIR = ratio of AC to DC inductor current, typi-

OUT

PEAK

300kHz

L =

< 100mV, as it is a key parameter for effi-

= maximum DC load current

= I

cally 0.3; should be selected for >0.15

2 and wind it with the largest-diameter

LOAD

). The following equation includes a

IN(MAX)

OUT IN(MAX)

(

(aluminum alloy) or even pow-

OUT

2 x f x L x V

x f x I

IN(MAX)

OUT

- V

OUT

x LIR

IN(MAX)

PEAK

- V

)

rating greater

OUT

), and DC

)

MAX1631AEAI Maxim Integrated Products, MAX1631AEAI Datasheet - Page 18

MAX1631AEAI

Specifications of MAX1631AEAI

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