ncp5424adr2 ON Semiconductor, ncp5424adr2 Datasheet - Page 16
ncp5424adr2
Manufacturer Part Number
ncp5424adr2
Description
Dual Synchronous Buck Controller With Input Current Sharing
Manufacturer
ON Semiconductor
Datasheet
1.NCP5424ADR2.pdf
(18 pages)
low value, typically less than 10 mW. Such a resistor can be
either a discrete component or a PCB trace. The resistance
value of a discrete component can be more precise than a
PCB trace, but the cost is also greater.
very precise because all the values can be designed to
specific tolerances. However, the disadvantage of using a
sense resistor is its additional constant power loss and heat
generation.
the intrinsic resistance of the inductor. A model of an
inductor reveals that the windings of an inductor have an
effective series resistance (ESR).
measured with a simple parallel circuit: an RC integrator. If
the value of R
then the voltage measured across the capacitor C will be:
value of 0.1 mF is recommended. The value of R
selected according to:
consult manufacturer’s datasheet for specific details.
current limit of:
20 A. If an increased current limit is required, a resistor
divider can be added.
winding resistance of the inductor are that efficiency is
maximized and heat generation is minimized. The tolerance
of the inductor ESR must be factored into the design of the
In a high current supply, the sense resistor will be a very
Setting the current limit using an external sense resistor is
Inductor ESR.
The voltage drop across the inductor ESR can be
Selecting Components.
Typical values for inductor ESR range in the low m;
Selection of components at these values will result in a
Given an ESR value of 3.5 mW, the current limit becomes
The advantages of setting the current limit by using the
GATE(H)
V
IS+
IS−
GATE(L)
CC
Figure 9. Inductor ESR Current Sensing
S1
and C are chosen such that:
Another means of sensing current is to use
R SENSE + 0.070 V
V C + ESR
R S1 +
I LIM + 0.070 V
ESR
L
RS1
L
+ R S1 C
Select the capacitor C first. A
ESR
ESR
I LIMIT
1
ESR
I LIM
C
C
S1
http://onsemi.com
can be
Co
NCP5424
16
current limit. Finally, one or two more components are
required for this approach than with resistor sensing.
Adding External Slope Compensation
stringent load transient requirements. One of the key factors
in achieving tight dynamic voltage regulation is low ESR.
Low ESR at the regulator output results in low output
voltage ripple. The consequence is, however, that very little
voltage ramp exists at the control IC feedback pin (V
resulting in increased regulator sensitivity to noise and the
potential for loop instability. In applications where the
internal slope compensation is insufficient, the performance
of the NCP5424−based regulator can be improved through
the addition of a fixed amount of external slope
compensation at the output of the PWM Error Amplifier (the
COMP pin) during the regulator off−time. Referring to
Figure 8, the amount of voltage ramp at the COMP pin is
dependent on the gate voltage of the lower (synchronous)
FET and the value of resistor divider formed by R1and R2.
where:
compensation scheme results in improved control loop
stability provided that the RC filter time constant is smaller
than the off−time cycle duration (time during which the
lower MOSFET is conducting). It is important that the series
combination of R1 and R2 is high enough in resistance to
avoid loading the GATE(L) pin. Also, C1 should be very
small (less than a few nF) to avoid heating the part.
V SLOPECOMP + V GATE(L)
Today’s voltage regulators are expected to meet very
V
V
R1, R2 = voltage divider resistors;
t = t
The artificial voltage ramp created by the slope
NCP5424
= RC constant determined by C1 and the parallel
SLOPECOMP
GATE(L)
combination of R1, R2 neglecting the low driver
output impedance.
ON
Proper Voltage Ramp at the Beginning of
GATE(L)
Figure 10. Small RC Filter Provides the
COMP
or t
= lower MOSFET gate voltage;
OFF
= amount of slope added;
(switch off−time);
Each On−Time Cycle
R2
C
COMP
R1 ) R2
R2
To Synchronous
C1
FET
(1 * e
R1
−t
FB
t )
),
Related parts for ncp5424adr2
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
Dual Synchronous Buck Controller
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
EVAL BOARD FOR NCP5424
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
ON Semiconductor [VOLTAGE REGULATOR]
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
357-036-542-201 CARDEDGE 36POS DL .156 BLK LOPRO
Manufacturer:
ON Semiconductor
Datasheet:
Part Number:
Description:
Manufacturer:
ON Semiconductor
Datasheet: