MAX15023EVKIT+ Maxim Integrated Products, MAX15023EVKIT+ Datasheet - Page 23

MAX15023EVKIT+

Manufacturer Part Number

MAX15023EVKIT+

Description

KIT EVALUATION FOR MAX15023 CTLR

Manufacturer

Maxim Integrated Products

Datasheets

1.MAX15023ETG.pdf (28 pages)

2.MAX15023EVKIT.pdf (10 pages)

Specifications of MAX15023EVKIT+

Main Purpose

DC/DC, Step Down

Outputs And Type

2, Non-Isolated

Voltage - Output

1.2V, 3.3V

Current - Output

10A, 5A

Voltage - Input

9 ~ 16V

Regulator Topology

Buck

Frequency - Switching

500kHz

Board Type

Fully Populated

Utilized Ic / Part

MAX15023

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Power - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

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To estimate the temperature rise of the die, use the fol-

lowing equation:

where θ

of the package, P

and T

for the 24-pin TQFN package on multilayer boards, with

the conditions specified by the respective JEDEC stan-

dards (JESD51-5, JESD51-7). If actual operating condi-

tions significantly deviate from those described in the

JEDEC standards, then an accurate estimation of the

junction temperature requires a direct measurement of

the case temperature (T

ture can be calculated using the following equation:

Use 3°C/W as θ

TQFN package. The case-to-ambient thermal resis-

tance (θ

ferred from the PCB to the ambient. Therefore, solder

the exposed pad of the TQFN package to a large cop-

per area to spread heat through the board surface,

minimizing the case-to-ambient thermal resistance. Use

large copper areas to keep the PCB temperature low.

The MAX15023 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 MOS-

FET determines the appropriate boost capacitance

values (C

to the following equation:

where Qg is the total gate charge of the high-side

MOSFET and ∆V

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

∆V

significantly degraded (e.g., ∆V

300mV) when determining C

capacitor should be a low-ESR ceramic capacitor. A

minimum value of 100nF is recommended.

BST_

such that the available gate drive voltage is not

is the ambient temperature. The θ

BST_

) is dependent on how well the heat is trans-

is the junction-to-ambient thermal resistance

Boost Flying-Capacitor Selection

in Typical Application Circuits ) according

BST_

______________________________________________________________________________________

BST

is power dissipated in the device,

= T

thermal resistance for the 24-pin

= T

is the voltage variation allowed on

). Then, the junction tempera-

+ (P

∆

Wide 4.5V to 28V Input, Dual-Output

BST

BST_

x θ

. The boost flying-

BST_

)

= 100mV to

Synchronous Buck Controller

is 36°C/W

Make the controller ground connections as follows: cre-

ate a small analog ground plane near the IC or use a

dedicated internal plane. Connect this plane to SGND

and use this plane for the ground connection for the IN

bypass capacitor, compensation components, feed-

back dividers, RT resistor, and LIM_ resistors.

If possible, place all power components on the top side

of the board, and run the power stage currents (espe-

cially the one having large high-frequency components)

using traces or copper fills on the top side only, without

adding vias.

On the top side, lay out a large PGND copper area for

the output of channels 1 and 2, and connect the bottom

terminals of the high-frequency input capacitors, output

capacitors, and the source terminals of the low-side

MOSFETs to that area.

Then, make a star connection of the SGND plane to the

top copper PGND area with few vias in the vicinity of

the source terminal sensing. Do not connect PGND and

SGND anywhere else. Refer to the MAX15023

Evaluation Kit data sheet for guidance.

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 vs. 1oz) to enhance efficiency.

Place the controller IC adjacent to the synchronous rec-

tifier MOSFETs (NL_) and keep the connections for LX_,

PGND_, DH_, and DL_ short and wide. Use multiple

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

tom side. The gate current traces must be short and

wide, measuring 50 mils to 100 mils wide if the low-side

MOSFET is 1in from the controller IC. Connect each

PGND trace from the IC close to the source terminal of

the respective low-side MOSFET.

Route high-speed switching nodes (BST_, LX_, DH_,

and DL_) away from the sensitive analog areas (RT,

COMP_, LIM_, and FB_). Group all SGND-referred and

feedback components close to the IC. Keep the FB_

and compensation network nets as small as possible to

prevent noise pickup.

Applications Information

PCB Layout Guidelines

MAX15023EVKIT+ Maxim Integrated Products, MAX15023EVKIT+ Datasheet - Page 23

MAX15023EVKIT+

Specifications of MAX15023EVKIT+

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