NCP3170AGEVB ON Semiconductor, NCP3170AGEVB Datasheet - Page 24

NCP3170AGEVB

Manufacturer Part Number

NCP3170AGEVB

Description

BOARD EVALUATION NCP3170ADR2G

Manufacturer

ON Semiconductor

Series

-r

Datasheet

1.NCP3170ADR2G.pdf (25 pages)

Specifications of NCP3170AGEVB

Design Resources

NCP3170 Schematic NCP3170AGEVB BOM

Main Purpose

DC/DC, Step Down

Outputs And Type

1, Non-Isolated

Power - Output

Voltage - Output

Adj down to 0.8V

Current - Output

Voltage - Input

4.5 ~ 18 V

Regulator Topology

Buck

Frequency - Switching

500kHz

Board Type

Fully Populated

Utilized Ic / Part

NCP3170

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

NCP3170AGEVBOS

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the system for which the equations above detailed the loss

mechanisms. The control portion of the IC power

dissipation is determined by the formula below:

designer can calculate the required thermal impedance to

maintain a specified junction temperature at the worst case

ambient temperature. The formula for calculating the

junction temperature with the package in free air is:

affected by the PCB layout. Extra care should be taken by

users during the design process to ensure that the IC will

operate under the recommended environmental conditions.

As with any power design, proper laboratory testing should

be performed to ensure the design will dissipate the required

power under worst case operating conditions. Variables

considered during testing should include maximum ambient

qJA

The NCP3170 is the major source of power dissipation in

Once the IC power dissipations are determined, the

The thermal performance of the NCP3170 is strongly

Figure 52. Recommended Signal Layout

= Power dissipation of the IC

= Thermal resistance junction to ambient of

= Ambient temperature

= Junction temperature

= Control power dissipation

= Input voltage

= Control circuitry current draw

the regulator package

+ T

+ I

) P

qJA

(eq. 51)

(eq. 52)

http://onsemi.com

temperature, minimum airflow, maximum input voltage,

maximum loading, and component variations (i.e., worst

case MOSFET R

for the best electric and thermal performance. Figure 53

illustrates a PCB layout example of the NCP3170.

1. The VSW pin is connected to the internal PFET

2. The user should not use thermal relief connections

3. The input capacitor should be connected to the

4. A ground plane on the bottom and top layers of the

5. Create copper planes as short as possible from the

6. Create a copper plane on all of the unused PCB

7. Keep sensitive signal traces far away from the

and NFET drains, which are a low resistance

thermal path. Connect a large copper plane to the

VSW pin to help thermal dissipation. If the PG pin

is not used in the design, it can be connected to the

VSW plane, further reducing the thermal

impedance. The designer should ensure that the

VSW thermal plane is rounded at the corners to

reduce noise.

to the VIN and the PGND pins. Construct a large

plane around the PGND and VIN pins to help

thermal dissipation.

VIN and PGND pins as close as possible to the IC.

PBC board is preferred. If a ground plane is not

used, separate PGND from AGND and connect

them only at one point to avoid the PGND pin

noise coupling to the AGND pin.

VSW pin to the output inductor, from the output

inductor to the output capacitor, and from the load

to PGND.

area and connect it to stable DC nodes such as:

VSW pins or shield them.

Figure 53. Recommend Thermal Layout

, GND, or V

DS(on)

). Several layout tips are listed below

OUT

NCP3170AGEVB ON Semiconductor, NCP3170AGEVB Datasheet - Page 24

NCP3170AGEVB

Specifications of NCP3170AGEVB

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