NCP5425_06 ONSEMI [ON Semiconductor], NCP5425_06 Datasheet - Page 12

NCP5425_06

Manufacturer Part Number

NCP5425_06

Description

Dual Synchronous Buck Controller

Manufacturer

ONSEMI [ON Semiconductor]

Datasheet

1.NCP5425_06.pdf (22 pages)

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Figure 8A − Basic Current Sensing

the voltage at pin +Is exceeds the voltage at pin –Is by 70 mV

(nominal), the internal current sense comparator offset will

be overcome. For this case, the current limit threshold is

equal to (70 mV/Rx) amps. An obvious disadvantage of the

basic configuration is the power supply designer has no

control over the 70 mV offset, and limited control over the

value of Rx. Therefore, he or she has little flexibility to set

a specific current limit. Configurations (8B) and (8D) depict

techniques to increase and decrease, respectively, the

threshold current.

Figure 8B – Increasing the Current Threshold

only a portion of the voltage across Rx appears across C1.

If, for example, R1 = R2, it will require a 140 mV drop

across Rx to overcome the internal 70 mV current sense

comparator offset. For optimum compensation with this

configuration, R1 and R2 should be selected such that Rx is

equal to their equivalent parallel resistance.

Figure 8C – Bias Current Compensation

error, since the bias currents of the current sense comparator

inputs flow through unbalanced resistance paths. The

addition of R3 in configuration 8C, where R3 = R1, restores

a balanced input resistance, such that any voltage drops

introduced by bias currents will cancel (assuming the +Is

and –Is bias currents are equal). In the case of configuration

8B, R3 would be made equal to the equivalent resistance of

R1 and R2 in parallel.

Represents a basic inductor sensing configuration. When

Addition of resistor R2 forms a voltage divider such that

Configurations 8A, 8B and 8D all introduce a potential

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NCP5425

Figure 8D – Decreasing the Current Threshold

to develop, by scaling the output voltage, a small voltage

drop across R3 that opposes the internal current sense

comparator offset. For example, if Vout = 1.2 V, R3 = 200 W,

and R4 = 11.8 K, a DC voltage drop of 20 mV will be

established across R3. The polarity of that voltage is such

that it opposes the internal 70 mV offset, effectively

reducing it to 50 mV. The current threshold is now given by

(50 mV/Rx) instead of (70 mV/Rx).

Current Limiting

Cycle−by−Cycle current limiting. Comparators with

internal 70 mV offsets provide the references for setting

current limit. Once a voltage greater than 70 mV is applied

to the current limiting comparator, it resets that channel’s

output RS flip flop. This terminates the PWM pulse for the

cycle and limits the energy delivered to the load. One

advantage of this current limiting scheme is that the

NCP5425 will limit large transient currents yet resume

normal operation on the following cycle. A second benefit

of limiting the PWM pulse width is, in an input power

sharing application, one controller can be current limiting

while the other supplies the remaining load current.

Output Enable

implemented by pulling the COMP pins low. Driving the

COMP pins below the 0.20 V PWM comparator offset

voltage disables switching of the GATE drivers.

A voltage divider comprised of R3 and R4 is introduced

Both channels of the NCP5425 employ identical

On/Off control of the regulator outputs can be

NCP5425_06 ONSEMI [ON Semiconductor], NCP5425_06 Datasheet - Page 12

NCP5425_06

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