CS5171EDR8G ON Semiconductor, CS5171EDR8G Datasheet - Page 11

CS5171EDR8G

Manufacturer Part Number

CS5171EDR8G

Description

IC MULTI CONFIG SYNC 1.5A 8SOIC

Manufacturer

ON Semiconductor

Type

Step-Up (Boost), Flyback, Forward Converter, Sepicr

Datasheet

1.CS5171GDR8G.pdf (21 pages)

Specifications of CS5171EDR8G

Internal Switch(s)

Yes

Synchronous Rectifier

Number Of Outputs

Current - Output

1.5A

Frequency - Switching

280kHz

Voltage - Input

2.7 ~ 30 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Mounting Style

SMD/SMT

Rohs Compliant

YES

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Voltage - Output

Power - Output

Lead Free Status / Rohs Status

Lead free / RoHS Compliant

Other names

CS5171EDR8GOSTR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

CS5171EDR8G

Manufacturer:

ON/安森美

Quantity:

20 000

Current page: 11 of 21
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Switch Driver and Power Switch

section to drive the output power switch. The switch is

grounded through emitter resistors (63 mW total) to the

PGND pin. PGND is not connected to the IC substrate so that

switching noise can be isolated from the analog ground. The

peak switching current is clamped by an internal circuit. The

clamp current is guaranteed to be greater than 1.5 A and

varies with duty cycle due to slope compensation. The

power switch can withstand a maximum voltage of 40 V on

the collector (V

is typically less than 1 V to minimize power dissipation.

Short Circuit Condition

the inductor current will increase during the whole

switching cycle, causing excessive current to be drawn from

the input power supply. Since control ICs don’t have the

means to limit load current, an external current limit circuit

(such as a fuse or relay) has to be implemented to protect the

load, power supply and ICs.

prevents damage to the chip and external components. This

feature reduces the minimum duty cycle and allows the

transformer secondary to absorb excess energy before the

switch turns back on.

Startup waveforms shown in Figure 30 are measured in the

boost converter demonstrated in the Application Diagram

on the page 2 of this document. Recorded after the input

voltage is turned on, this waveform shows the various

phases during the power up transition.

voltage, the V

current conducts directly from the input power source to the

output through the inductor and diode. Once V

The switch driver receives a control signal from the logic

When a short circuit condition happens in a boost circuit,

In other topologies, the frequency shift built into the IC

The CS517x can be activated by either connecting the

When the V

Figure 30. Startup Waveforms of Circuit Shown in

pin to a voltage source or by enabling the SS pin.

the Application Diagram. Load = 400 mA.

pin). The saturation voltage of the switch

voltage is below the minimum supply

pin is in high impedance. Therefore,

reaches

http://onsemi.com

OUT

approximately 1.5 V, the internal power switch briefly turns

on. This is a part of the CS517x’s normal operation. The

turn−on of the power switch accounts for the initial current

swing.

internal power switch starts to switch and a voltage pulse can

be seen at the V

FB pin, the built−in frequency shift feature reduces the

switching frequency to a fraction of its nominal value,

reducing the minimum duty cycle, which is otherwise

limited by the minimum on−time of the switch. The peak

current during this phase is clamped by the internal current

limit.

increases to its nominal value, and the peak current begins

to decrease as the output approaches the regulation voltage.

The overshoot of the output voltage is prevented by the

active pull−on, by which the sink current of the error

amplifier is increased once an overvoltage condition is

detected. The overvoltage condition is defined as when the

FB pin voltage is 50 mV greater than the reference voltage.

COMPONENT SELECTION

Frequency Compensation

desirable transient response and DC regulation while

ensuring the stability of the system. A typical compensation

network, as shown in Figure 31, provides a frequency

response of two poles and one zero. This frequency response

is further illustrated in the Bode plot shown in Figure 32.

DC accuracy over line and load variations. The DC gain of

a transconductance error amplifier can be calculated as

follows:

where:

amplifier output resistance and C1 as:

Gain DC + G M

f P1 +

When the V

When the FB pin voltage rises above 0.4 V, the frequency

The goal of frequency compensation is to achieve

The high DC gain in Figure 32 is desirable for achieving

The low frequency pole, f

Figure 31. A Typical Compensation Network

= error amplifier output resistance ≈ 1 MW.

= error amplifier transconductance;

2pC1R O

CS5171

pin voltage rises above the threshold, the

R O

pin. Detecting a low output voltage at the

GND

P1,

is determined by the error

CS5171EDR8G ON Semiconductor, CS5171EDR8G Datasheet - Page 11

CS5171EDR8G

Specifications of CS5171EDR8G

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