NCP3170AGEVB ON Semiconductor, NCP3170AGEVB Datasheet - Page 21

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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amplifier.

amplifier and the impedance networks Z

and external Z

network has to provide a closed loop transfer function with

the highest 0dB crossing frequency to have fast response and

the highest gain in DC conditions, so as to minimize load

regulation issues. A stable control loop has a gain crossing

with −20 dB/decade slope and a phase margin greater than

45°. Include worst−case component variations when

determining phase margin. To start the design, a resistor

value should be chosen for R

components can be chosen. A good starting value is 24.9 kW.

to be adjusted down to 0.8 V via an external resistor divider

network. The regulator will maintain 0.8 V at the feedback

pin. Thus, if a resistor divider circuit was placed across the

feedback pin to V

voltage proportional to the resistor divider network in order

to maintain 0.8 V at the FB pin.

above and the output voltage is shown in Equation 40:

Figure 45. Pseudo Type III Transconductance Error

Figure 45 shows a pseudo Type III transconductance error

The compensation network consists of the internal error

The NCP3170 allows the output of the DC−DC regulator

The relationship between the resistor divider network

ZFB

Figure 46. Feedback Resistor Divider

OUT

+ R

, the regulator will regulate the output

, C

Amplifier

, and C

IEA

OUT

VREF

REF

* V

ZIN

from which all other

). The compensation

REF

R 1

R 2

, R

, and C

(eq. 40)

http://onsemi.com

)

associated standard R

below.

Transconductance Error Amplifier can be calculated using

the method described below. The method serves to provide

a good starting place for compensation of a power supply.

The values can be adjusted in real time using the

compensation

http://www.onsemi.com/pub/Collateral/COMPCALC.ZIP

be setup at FPO to decrease at −20dB per decade:

used to calculate the transconductance output compensation

network as follows:

cross

OUTPUT VOLTAGE SETTINGS

OUT

REF

The most frequently used output voltages and their

The compensation components for the Pseudo Type III

The first pole to crossover at the desired frequency should

The crossover combined compensation network can be

0.8

1.0

1.1

1.2

1.5

1.8

2.5

3.3

5.0

(V)

= Top resistor divider

= Bottom resistor divider

= Output voltage

= Regulator reference voltage

= Cross over frequency

= Pole frequency to meet crossover

= DC gain of the plant

= Compensation capacitor

= Pole frequency

15.4 nF +

1.99 kHz +

frequency

and R

0.242

24.9

(kW)

50 kHz

42.65

CROSS

tool

1.994 kHz

values are listed in the table

200 ms

*³

Open

66.5

49.9

28.7

8.06

4.64

11.8

100

(kW)

CompCalc

(eq. 41)

(eq. 42)

NCP3170AGEVB ON Semiconductor, NCP3170AGEVB Datasheet - Page 21

NCP3170AGEVB

Specifications of NCP3170AGEVB

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