MAX1808EUB+ Maxim Integrated, MAX1808EUB+ Datasheet - Page 18

MAX1808EUB+

Manufacturer Part Number

MAX1808EUB+

Description

Current & Power Monitors & Regulators

Manufacturer

Maxim Integrated

Datasheet

1.MAX1808EUB.pdf (23 pages)

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The MAX15026 uses a bootstrap circuit to generate the

necessary gate-to-source voltage to turn on the high-

side MOSFET. The selected n-channel high-side

MOSFET determines the appropriate boost capaci-

tance value (C

according to the following equation:

where Q

MOSFET and ∆V

the high-side MOSFET driver after turn-on. Choose

∆V

cantly degraded (e.g. ∆V

determining C

the boost flying capacitor with a minimum value of

100nF.

The maximum power dissipation of the device depends

on the thermal resistance from the die to the ambient

environment and the ambient temperature. The thermal

resistance depends on the device package, PCB cop-

per area, other thermal mass, and airflow.

The power dissipated into the package (P

on the supply configuration (see the Typical Application

Circuits ). Use the following equation to calculate power

dissipation:

where I

lator, I

vers at DRV, and I

MAX15026 without the contribution of the I

in the Typical Operating Characteristics . For example, in

the application circuit of Figure 5, I

Use the following equation to estimate the temperature

rise of the die:

where θ

ance of the package, P

device, and T

24.4°C/W for 14-pin TDFN package on multilayer

boards, with the conditions specified by the respective

JEDEC standards (JESD51-5, JESD51-7). An accurate

Low-Cost, Small, 4.5V to 28V Wide Operating

Range, DC-DC Synchronous Buck Controller

MAX15026

DRV

BST

= V

= (V

DRV

so the available gate-drive voltage is not signifi-

LDO

is the supply current consumed by the dri-

is the total gate charge of the high-side

is the junction-to-ambient thermal imped-

is the current supplied by the internal regu-

so that P

- V

BST

is the ambient temperature. The θ

BST

. Use a low-ESR ceramic capacitor as

) x I

in the Typical Application Circuits )

= T

is the voltage variation allowed on

LDO

BST

= V

is the supply current of the

BST

+ (P

+ V

is power dissipated in the

∆

x (I

= 100mV to 300mV) when

DRV

BST

DRV

x θ

Power Dissipation

x I

LDO

Boost Capacitor

+ I

DRV

)

= I

+ V

DRV

) depends

, as given

+ I

x I

and

estimation of the junction temperature requires a direct

measurement of the case temperature (T

operating conditions significantly deviate from those

described in the JEDEC standards. The junction tem-

perature is then:

Use 8.7°C/W as θ

TDFN package. The case-to-ambient thermal imped-

ance (θ

ferred from the PCB to the ambient. Solder the exposed

pad of the TDFN package to a large copper area to

spread heat through the board surface, minimizing the

case-to-ambient thermal impedance. Use large copper

areas to keep the PCB temperature low.

Place all power components on the top side of the

board, and run the power stage currents using traces

or copper fills on the top side only. Make a star connec-

tion on the top side of traces to GND to minimize volt-

age drops in signal paths.

Keep the power traces and load connections short,

especially at the ground terminals. This practice is

essential for high efficiency and jitter-free operation. Use

thick copper PCBs (2oz or above) to enhance efficiency.

Place the MAX15026 adjacent to the synchronous recti-

fier MOSFET, preferably on the back side, to keep LX,

GND, DH, and DL traces short and wide. Use multiple

small vias to route these signals from the top to the bot-

tom side. Use an internal quiet copper plane to shield

the analog components on the bottom side from the

power components on the top side.

Make the MAX15026 ground connections as follows:

create a small analog ground plane near the device.

Connect this plane to GND and use this plane for the

ground connection for the V

pensation components, feedback dividers, V

tor, RT resistor, and LIM resistor.

Use Kelvin sense connections for LX and GND to the

synchronous rectifier MOSFET for current limiting to

guarantee the current-limit accuracy.

Route high-speed switching nodes (BST, LX, DH, and DL)

away from the sensitive analog areas (RT, COMP, LIM,

and FB). Group all GND-referred and feedback compo-

nents close to the device. Keep the FB and compensation

network as small as possible to prevent noise pickup.

) is dependent on how well the heat is trans-

= T

thermal impedance for the 14-pin

+ (P

PCB Layout Guidelines

bypass capacitor, com-

x θ

)

) when actual

Maxim Integrated

capaci-

MAX1808EUB+ Maxim Integrated, MAX1808EUB+ Datasheet - Page 18

MAX1808EUB+

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