MAX17061ETI+ Maxim Integrated Products, MAX17061ETI+ Datasheet - Page 20

MAX17061ETI+

Manufacturer Part Number

MAX17061ETI+

Description

IC LED DRVR WHITE BCKLGT 28-TQFN

Manufacturer

Maxim Integrated Products

Type

Backlight, White LEDr

Datasheet

1.MAX17061ETI.pdf (26 pages)

Specifications of MAX17061ETI+

Topology

PWM, Step-Up (Boost)

Number Of Outputs

Internal Driver

Yes

Type - Primary

Automotive, Backlight

Type - Secondary

White LED

Frequency

1MHz

Voltage - Supply

4.5 V ~ 26 V

Voltage - Output

Mounting Type

Surface Mount

Package / Case

28-TQFN Exposed Pad

Operating Temperature

-40°C ~ 85°C

Current - Output / Channel

30mA

Internal Switch(s)

Yes

Operating Supply Voltage

5 V

Maximum Supply Current

2 mA

Maximum Power Dissipation

1667 mW

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Efficiency

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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To ensure the stable operation, the MAX17061 includes

slope compensation, which sets the minimum inductor

value. In continuous-conduction mode (CCM), the mini-

mum inductor value is calculated with the following

equation:

where 24.7mV is a scale factor from the slope compen-

sation, the L

stable operation in CCM, and R

equivalent sensing scale factor from the controller’s

internal current-sense circuit.

The controller can also operate in discontinuous con-

duction mode (DCM). In this mode, the inductor value

can be lower, but the peak inductor current is higher

than in CCM. In DCM, the maximum inductor value is

calculated with the following equation:

where the L

for DCM,

and I

The output current capability of the step-up converter is

a function of current limit, input voltage, operating fre-

quency, and inductor value. Because the slope com-

pensation is used to stabilize the feedback loop, the

inductor current limit depends on the duty cycle, and is

determined with the following equation:

where 24.7mV is the scale factor from the slope com-

pensation, 1.9A is a typical current limit at 75% duty

cycle, and D is the duty cycle.

The output current capability depends on the current-

limit value and operating mode. The maximum output

current in CCM is governed by the following equation:

8-String White LED Driver with

SMBus for LCD Panel Applications

LDCM

CCM MIN

______________________________________________________________________________________

OUT(MAX)

(

MAX

OUT CCM MAX

)

CCM(MIN)

LIM

DCM(MAX)

is the nominal regulator efficiency (85%),

)

is the maximum output current.

OUT MAX

1 9

OSC MAX

(

OUT MAX

is the minimum inductor value for

(

2 24 7

is the maximum inductor value

)

24 7

)

(

IN MIN

)

LIM

DIODE

(

IN MIN

)

mV f

(

OUT MAX

)

DIODE

. 0 5

0 75

)

=12mΩ (typ) is the

(

OSC MIN

OSC

D V

(

)

IN MIN

(

OUT MAX

)

(

)

where I

nominal regulator efficiency (85%), and D is the duty

cycle. The corresponding duty cycle for this current is:

where V

diode and R

(0.15Ω typ).

The maximum output current in DCM is governed by

the following equation:

The inductance, peak current rating, series resistance,

and physical size should all be considered when selecting

an inductor. These factors affect the converter’s operating

mode, efficiency, maximum output load capability, tran-

sient response time, output voltage ripple, and cost.

The maximum output current, input voltage, output volt-

age, and switching frequency determine the inductor

value. Very high inductance minimizes the current rip-

ple, and therefore reduces the peak current, which

decreases core losses in the inductor and I

the entire power path. However, large inductor values

also require more energy storage and more turns of

wire, which increases physical size and I

losses. Low inductor values decrease the physical size,

but increase the current ripple and peak current.

Finding the best inductor involves the compromises

among circuit efficiency, inductor size, and cost.

In choosing an inductor, the first step is to determine

the operating mode: continuous conduction mode

(CCM) or discontinuous conduction mode (DCM). The

MAX17061 has a fixed internal slope compensation that

requires minimum inductor value. When CCM mode is

chosen, the ripple current and the peak current of the

inductor can be minimized. If a small-size inductor is

required, DCM mode can be chosen. In DCM mode,

the inductor value and size can be minimized, but the

inductor ripple current and peak current are higher

than those in CCM. The controller can be stable, inde-

pendent of the internal slope compensation mode, but

there is a maximum inductor value requirement to

ensure the DCM operating mode.

OUT DCM MAX

LIM

DIODE

is the current limit calculated above,

is the forward voltage of the rectifier

(

is the internal MOSFET’s on-resistance

OUT

)

LIM

L I

OUT

LIM

Inductor Selection

DIODE

OSC

R losses in

R copper

is the

MAX17061ETI+ Maxim Integrated Products, MAX17061ETI+ Datasheet - Page 20

MAX17061ETI+

Specifications of MAX17061ETI+

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