IRF JMK212BJ476MG-T

PD97512
IR3838MPbF
SupIRBuck
TM
HIGHLY INTEGRATED 10A
SINGLE-INPUT VOLTAGE, SYNCHRONOUS BUCK REGULATOR
Features
Description
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The IR3838 SupIRBuckTM is an easy-to-use, fully
integrated and highly efficient DC/DC regulator.
The onboard PWM controller and MOSFETs
make IR3838 a space-efficient solution, providing
accurate power delivery for low output voltage
applications.
Greater than 96% Maximum Efficiency
Single 16V Application
Single 5V Application
Wide Output Voltage Range: 0.6V to 0.9*Vin
Continuous 10A Load Capability
Programmable Switching Frequency up to 1.5MHz
Internal Digital Soft-Start
Enable Input with Voltage Monitoring Capability
Hiccup Mode Over Current Protection
Internal LDO
External Synchronization
Enhanced PreBias Start up
External Reference for Margining Purposes
Input for Tracking Applications
Integrated MOSFET Drivers and Bootstrap Diode
Operating Junction Temp: -40oC <Tj<125oC
Thermal Shut Down
Power Good Output with tracking capability
Over Voltage Detection Feature
Pin Compatible with 6A and 14A Versions
Small Size 5mmx6mm PQFN, 0.9 mm Height
Lead-free, Halogen-free and RoHS Compliant
Applications
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Netcom and Telecom Applications
Data Center Applications
Distributed Point of Load Power Architectures
IR3838 is a versatile regulator which offers
programmability of switching frequency and
current limit while operates in wide input and
output voltage range.
The switching frequency is programmable from
250kHz to 1.5MHz for an optimum solution.
It also features important protection functions,
such as Pre-Bias startup, hiccup current limit and
thermal shutdown to give required system level
security in the event of fault conditions.
IR3838 offers margining capability through Vref
pin. During the margining operation, PGood
tracks Vref via feedback to ensure correct status
of the output voltage.
The internal LDO enables the device to operate
from a single supply. This internal LDO can be
bypassed when an external bias voltage is
available.
Fig. 1. Typical application diagram
Rev 1.41
1
IR3838MPbF
ABSOLUTE MAXIMUM RATINGS
(Voltages referenced to GND unless otherwise specified)
•
PVin, Vin
……………………………………………… -0.3V to 25V
•
Vcc/LDO_out ……………….……..……..……….…… -0.3V to 8V (Note2)
•
Boot
……………………………………..……….….. -0.3V to 33V
•
SW
…………………………………………..……… -0.3V to 25V (DC), -4V to 25V (AC, 100ns)
•
Boot to SW
•
OCset
•
Input / output Pins
•
PGnd to Gnd ……………...………………….…….…. -0.3V to +0.3V
•
Storage Temperature Range .................................... -55°C To 150°C
•
Junction Temperature Range ................................... -40°C To 150°C (Note2)
•
ESD Classification …………………………… ……… JEDEC(2KV)
•
Moisture sensitivity level………………...……………. JEDEC Level 2 @260 °C (Note 5)
……..…………………………… …..…. -0.3V to Vcc+0.3V (Note1)
…………………………………………..…… -0.3V to 30V
………………………………... ... -0.3V to Vcc+0.3V (Note1)
Note1: Must not exceed 8V
Note2: Vcc must not exceed 7.5V for Junction Temperature between -10oC and -40oC
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the
device. These are stress ratings only and functional operation of the device at these or any other conditions
beyond those indicated in the operational sections of the specifications are not implied.
Package Information
5mm x 6mm Power QFN
(Top View)
11
13
12
PVin
SW
PGnd
θJA = 35 o C / W
θJ -PCB = 2 o C / W
Boot
14
Enable
15
Vp
16
1
10
17
Gnd
2
3
4
Fb Vref Comp Gnd
5
6
Vcc/LDO_out
9
Vin
8
Sync
7
Rt OCset PGood
ORDERING INFORMATION
Rev 1.41
PACKAGE
DESIGNATOR
PACKAGE
DESCRIPTION
PIN
COUNT
PARTS PER
REEL
M
IR3838MTRPbF
17
4000
M
IR3838MTR1PbF
17
750
2
IR3838MPbF
Block Diagram
Fig. 2. Simplified block diagram of the IR3838
Rev 1.41
3
IR3838MPbF
Pin Description
Pin Name
Description
1
Fb
Inverting input to the error amplifier. This pin is connected directly to the
output of the regulator via resistor divider to set the output voltage and
provide feedback to the error amplifier
2
Vref
3
Comp
4
Gnd
5
Rt
6
OCset
7
8
PGood
Sync
External reference voltage, can be used for margining operation. A
100nF capacitor should be connected between this pin and Gnd.
Output of error amplifier. An external resistor and capacitor network is
typically connected from this pin to Fb to provide loop compensation
Signal ground for internal reference and control circuitry
Use an external resistor from this pin to Gnd to set the switching
frequency
Current limit set point. A resistor from this pin to SW pin will set the
current limit threshold
Power Good status pin. Output is open drain. Connect a pull up resistor
from this pin to Vcc
External Synchronization, this pin is used to synchronize the device’s
switching with an external clock. It is recommended that the external
Sync clock be set to 20% above the free-running frequency. If not used,
this pin can be left floating.
Vin
Input voltage for Internal LDO. A 1.0µF capacitor should be connected
between this pin and PGnd. If external supply is connected to
Vcc/LDO_out pin, this pin should be left floating.
10
VCC
/LDO_out
Input Bias Voltage, output of internal LDO. Place a minimum 2.2µF cap
from this pin to PGnd
11
PGnd
Power Ground. This pin serves as a separated ground for the MOSFET
drivers and should be connected to the system’s power ground plane.
12
SW
Switch node. This pin is connected to the output inductor
13
PVin
Input voltage for power stage
14
Boot
Supply voltage for high side driver, a 100nF capacitor should be
connected between this pin and SW pin.
15
Enable
16
Vp
17
Gnd
9
Rev 1.41
Enable pin to turn on and off the device, if this pin is connected to PVin
pin through a resistor divider, input voltage UVLO can be implemented.
Input to error amplifier for tracking purposes
Signal ground for internal reference and control circuitry
4
IR3838MPbF
Recommended Operating Conditions
Symbol
PVin
Vin
Vcc/LDO_out
Boot to SW
Vo
Io
Fs
Tj
Definition
Input Voltage for power stage
Input Voltage for internal LDO *
Supply Voltage *
Supply Voltage
Output Voltage
Output Current
Switching Frequency
Junction Temperature
Min
Max
1.5
7.0
4.5
4.5
0.6
0
225
-40
16
16
6.5
7.5
0.9*Vin
10
1650
125
Units
V
A
kHz
o
C
* Vcc/LDO_out can be connected to an external regulated supply (≈ 5V). If so, the Vin input should be
left unconnected.
Electrical Specifications
Unless otherwise specified, these specification apply over, 7.0V<Vin=PVin<16V, Vref=0.6V
in 0oC<Tj< 125oC. Typical values are specified at Ta = 25oC.
PARAMETER
POWER STAGE
Power Losses
SYMBOL
Ploss
Top Switch
Rds(on)_Top
Bottom Switch
Rds(on)_Bot
Bootstrap Diode Forward
Voltage
SW leakage Current
SUPPLY CURRENT
Vin Supply Current (Standby)
Vin Supply Current (Dyn)
TEST CONDITION
Vin=12V, Vo=1.8V, Io=10A,
Fs=600kHz, L=0.6uH, Note4
VBoot -Vsw =5.0V,
ID=10A,Tj=25C
Iin(Standby)
Iin(Dyn)
TYP
MAX
2
Vcc=5.0V, ID=10A
I(Boot)= 30mA
Isw
MIN
180
W
17.1
26
8.5
11
260
470
SW=0V, Enable=0V
6
SW=0V, Enable=high, Vp=0V
14
Enable low , No Switching,
400
Enable high, Fs=500kHz,
Vin=12V
UNIT
12
mΩ
mV
µA
µA
mA
INTERNAL REGULATOR (LDO)
Output Voltage
IntVcc
IntVcc Dropout
IntVcc_drop
Short Circuit Current
Ishort
Vin(min)=7.0V, Io=0-50mA,
Cload=2.2uF
Io=50mA, Cload=2.2uF
4.7
5.2
5.7
V
50
150
mV
70
mA
INTERNAL DIGITAL SOFT START
Soft Start Clock Frequency
Soft Start Ramp Rate
Rev 1.41
Clk(SS)
Ramp(SS)
Note4
168
200
0.2
254
kHz
mV/us
5
IR3838MPbF
Electrical Specifications (continued)
Unless otherwise specified, these specification apply over, 7.0V<Vin=PVin<16V, Vref=0.6V
in 0oC<Tj< 125oC. Typical values are specified at Ta = 25oC.
PARAMETER
SYMBOL
TEST CONDITION
MIN
TYP
MAX
Vos_Vp
Vfb-Vp, Vp=0.6V, Vref >2.0V
-1
+1
Vos_Vref
Vfb-Vref, Vref=0.6V, Vp>2.0V
-1
1
UNIT
ERROR AMPLIFIER
Input Offset Voltage
%
Input Bias Current
IFb(E/A)
-1
+1
A
Input Bias Current
IVp(E/A)
-1
+1
A
Sink Current
Isink(E/A)
0.40
0.85
1.2
mA
Isource(E/A)
8
10
13
mA
Source Current
Slew Rate
Gain-Bandwidth Product
DC Gain
SR
Note4
7
12
20
V/s
GBWP
Note4
20
30
40
MHz
Gain
Note4
100
110
120
dB
3.4
3.5
3.75
V
150
220
mV
1.2
V
V
Maximum Voltage
Vmax(E/A)
Minimum Voltage
Vmin(E/A)
Common Mode Voltage
0
OSCILLATOR
Rt Voltage
Frequency Range
FS
0.665
0.7
0.735
Rt=59K
225
250
275
Rt=28.7K
450
500
550
Rt=9.53K, Note4
1350
1500
1650
kHz
Vramp
Note4
1.8
Vp-p
Ramp Offset
Ramp(os)
Note4
0.6
V
Min Pulse Width
Dmin(ctrl)
Note4
Ramp Amplitude
Max Duty Cycle
Dmax
70
Fs=250kHz
91
Fixed Off Time
Note4
Sync Frequency Range
20% above free running
frequency
Sync Pulse Duration
Sync Level Threshold
Sync High
%
225
100
VFB
ns
1650
kHz
ns
2
0.6
Vref pin floating, Vp=Vcc
o
Accuracy
300
200
Sync Low
REFERENCE VOLTAGE
Feedback Voltage
ns
o
0 C<Tj<125 C
o
o
-40 C<Tj<125 C, Note3
0.6
V
V
-1.0
+1.0
-2.0
+2.0
0.54
1.2
V
%
Vref margining voltage
Vref_marg
Sink Current
Isink_Vref
Vref=0.7V
19
25
µA
Source Current
Isource_Vref
Vref=0.5V
19
25
µA
Tracker Comparator Threshold
Tracker Comparator
Hysteresis
Rev 1.41
Tracker(upper)
Vref pulled up externally
1.35
1.5
1.6
Tracker(lower)
Vref pulled up externally
1.05
1.2
1.3
Tracker_Hys
Vref pulled up externally
220
300
420
V
mV
6
IR3838MPbF
Electrical Specifications (continued)
PARAMETER
SYMBOL
TEST CONDITION
MIN
TYP
MAX
Fs=250kHz
10.4
11.8
13.2
Fs=500kHz
21.5
24.4
27.3
Fs=1500kHz
68
77
86
Note4
-6
0
+6
UNIT
FAULT PROTECTION
OCSET Current
OC comp Offset Voltage
SS off time
IOCSET
VOFFSET
SS_Hiccup
4096
Thermal Shutdown
Note4
140
Thermal Hysteresis
Note4
20
°C
Vcc Rising Trip Level
4.06
4.26
4.46
VCC-Stop-Threshold
VCC_UVLO_Stop
Vcc Falling Trip Level
3.76
3.96
4.16
Enable-Start-Threshold
Enable_UVLO_Start
Supply ramping up
1.14
1.2
1.36
Enable-Stop-Threshold
Enable_UVLO_Stop
Supply ramping down
0.75
0.85
0.95
PGOOD
Power Good upper Threshold
Upper Threshold Delay
Power Good lower Threshold
Lower Threshold Delay
Soft Start Delay Time
PGood Voltage Low
Tracker Comparator Upper
Threshold
Tracker Comparator Lower
Threshold
Tracker Comparator Delay
Ien
VPG(upper)
VPG(upper)_Dly
VPG(lower)
VPG(lower)_Dly
Tdelay(Delay)
PG(voltage)
Enable=3.3V
mV
Cycles
UNDER VOLTAGE LOCKOUT
VCC-Start-Threshold
VCC_UVLO_Start
Enable leakage current
µA
10
V
V
µA
Fb Rising, Vref < 1.2V
115
%Vref
Fb Rising, Vref > 1.5V
115
%Vp
256/Fs
s
Fb Rising, Vref < 1.2V
85
%Vref
Fb Rising, Vref > 1.5V
85
%Vp
Fb Falling
Fb Rising
Note4
256/Fs
s
10
ms
IPgood=-5mA
0.5
VPG(tracker_upper)
Vp Rising, Vref > 1.5V
0.5
VPG(tracker_lower)
Vp Falling, Vref > 1.5V
0.3
Tdelay(tracker)
Vp Rising, Vref > 1.5V
256/Fs
V
V
s
Note3: Cold temperature performance is guaranteed via correlation using statistical quality control. Not tested in production.
Note4: Guaranteed by design but not tested in production
Note5: Upgrade to industrial/MSL2 level applies from date codes 1141 (marking explained on application note AN1132 page 2).
Products with prior date code of 1141 are qualified with MSL3 for Consumer market.
Rev 1.41
7
IR3838MPbF
Typical Efficiency and Power Loss Curves
Vin=12V, Vcc=5V (external), Io=1A-10A, Fs=600kHz, Room Temperature, No Air Flow
The table below shows the inductors used for each of the output voltages
in the efficiency measurement.
Vo [V]
1.2
1.8
3.3
5.0
L [µH]
0.51
0.72
1.2
1.2
MFR
Vitec
Wurth Elek.
Wurth Elek.
Delta
P/N
DCR [mΩ]
59PR9876N
0.29
744 325 072
1.3
744 325 120
1.8
MPL1055-1R2
2.9
98
96
Efficiency (%)
94
92
90
88
86
84
82
80
1
2
3
4
5
6
7
8
9
10
Load Current (A)
1.2V
1.8V
3.3V
5.0V
2.8
2.6
2.4
Power Loss (W)
2.2
2.0
1.8
1.6
1.4
1.2
1.0
0.8
0.6
0.4
0.2
1
2
3
4
5
6
7
8
9
10
Load Current (A)
1.2V
Rev 1.41
1.8V
3.3V
5.0V
8
IR3838MPbF
Typical Efficiency and Power Loss Curves
Vin=12V, Vcc/LDO_out=5.2V, Io=1A-10A, Fs=600kHz, Room Temperature, No Air Flow
The same inductors as listed on the previous page have been used.
98
96
Efficiency (%)
94
92
90
88
86
84
82
80
78
76
1
2
3
4
5
6
7
8
9
10
Load Current (A)
1.2V
1.8V
3.3V
5.0V
3.0
2.7
Power Loss (W)
2.4
2.1
1.8
1.5
1.2
0.9
0.6
0.3
1
2
3
4
5
6
7
8
9
10
Load Current (A)
1.2V
Rev 1.41
1.8V
3.3V
5.0V
9
IR3838MPbF
TYPICAL OPERATING CHARACTERISTICS (-40oC - 125oC), Fs=500 kHz
Iin(Dyn)
Iin(Standby)
12.5
400
380
360
12.3
340
320
12.1
[mA]
[µA]
300
280
260
11.9
240
220
11.7
200
180
160
-40
-20
0
20
40
60
80
100
120
11.5
140
-40
-20
0
20
40
Temp [ºC]
60
80
100
120
140
80
100
120
140
80
100
120
140
80
100
120
140
80
100
120
140
Temp [ºC]
FREQUENCY
IOCSET(500kHz)
27.5
550
540
26.5
530
25.5
510
[µA]
[kHz]
520
500
24.5
490
23.5
480
470
22.5
460
450
-40
-20
0
20
40
60
80
100
120
21.5
140
-40
-20
0
20
Temp [ºC]
Vcc(UVLO) Stop
4.46
4.16
4.41
4.11
4.36
4.06
4.31
4.01
[V]
[V]
60
Temp [ºC]
Vcc(UVLO) Start
4.26
3.96
4.21
3.91
4.16
3.86
4.11
3.81
3.76
4.06
-40
-20
0
20
40
60
80
100
120
-40
140
-20
0
20
40
60
Temp [ºC]
Temp [ºC]
Enable(UVLO) Stop
Enable(UVLO) Start
1.36
0.95
1.34
0.93
1.32
0.91
1.30
0.89
1.28
0.87
[V]
1.26
[V]
40
1.24
0.85
0.83
1.22
1.20
0.81
1.18
0.79
0.77
1.16
1.14
0.75
-40
-20
0
20
40
60
80
100
120
140
-40
-20
0
20
Temp [ºC]
40
60
Temp [ºC]
Vfb
Vcc_LDO
0.612
5.7
5.6
0.608
5.5
5.4
0.604
[V]
[V]
5.3
5.2
0.600
5.1
0.596
5.0
4.9
0.592
4.8
0.588
4.7
-40
-20
0
20
40
60
Temp [ºC]
Rev 1.41
80
100
120
140
-40
-20
0
20
40
60
Temp [ºC]
10
IR3838MPbF
Rdson of MOSFETs Over Temperature at Vcc=5V
24
22
Resistance [m-ohm]
20
18
16
14
12
10
8
6
-40
-20
0
20
40
60
80
100
120
140
6.25
6.5
Temperature [C]
Sync-FET
Ctrl-FET
Rdson of Sync-FET versus Vcc at different Temperatures
14
RDS_ON_Sync [mΩ]
13
12
11
10
9
8
7
6
5
4.5
4.75
5
-40C
Rev 1.41
5.25
0C
5.5
Vcc [V]
25C
65C
5.75
6
100C
125C
11
IR3838MPbF
Circuit Description
THEORY OF OPERATION
Introduction
The IR3838 uses a PWM voltage mode control
scheme with external compensation to provide
good noise immunity and maximum flexibility in
selecting inductor values and capacitor types.
The switching frequency is programmable from
250kHz to 1.5MHz and provides the capability of
optimizing the design in terms of size and
performance.
IR3838 provides precisely regulated output
voltage programmed via two external resistors
from 0.6V to 0.9*Vin.
The IR3838 operates with an internal bias supply
voltage of 5.2V (LDO) which is connected to the
Vcc/LDO_out pin. This allows operation with
single supply. The IC can also be operated with
an external supply from 4.5V to 6.5V, allowing an
extended operating input voltage (PVin) range
from 1.5V to 16V. For using the internal supply,
the Vin pin should be connected to PVin pin. If an
external supply is used, it should be connected to
Vcc/LDO_out pin and the Vin pin should be left
floating.
The device utilizes the on-resistance of the low
side MOSFET (sync FET) as current sense
element. This method enhances the converter’s
efficiency and reduces cost by eliminating the
need for external current sense resistor.
IR3838 includes two low Rds(on) MOSFETs using
IR’s HEXFET technology. These are specifically
designed for high efficiency applications.
Under-Voltage Lockout and POR
The under-voltage lockout circuit monitors the
voltage of Vcc/Ldo pin and the Enable input. It
assures that the MOSFET driver outputs remain
in the off state whenever either of these two
signals drop below the set thresholds. Normal
operation resumes once Vcc/LDO and Enable
rise above their thresholds.
The POR (Power On Ready) signal is generated
when all these signals reach the valid logic level
(see system block diagram). When the POR is
asserted the soft start sequence starts (see soft
start section).
Rev 1.41
Enable
The Enable features another level of flexibility for
start up. The Enable has precise threshold which
is internally monitored by Under-Voltage Lockout
(UVLO) circuit. Therefore, the IR3838 will turn on
only when the voltage at the Enable pin exceeds
this threshold, typically, 1.2V.
If the input to the Enable pin is derived from the
bus voltage by a suitably programmed resistive
divider, it can be ensured that the IR3838 does
not turn on until the bus voltage reaches the
desired level (Fig. 3). Only after the bus voltage
reaches or exceeds this level will the voltage at
Enable pin exceed its threshold, thus enabling
the IR3838. Therefore, in addition to being a logic
input pin to enable the IR3838, the Enable
feature, with its precise threshold, also allows the
user to implement an Under-Voltage Lockout for
the bus voltage (PVin).
This is desirable
particularly for high output voltage applications,
where we might want the IR3838 to be disabled
at least until PVin exceeds the desired output
voltage level.
Pvin (12V)
10. 2 V
Vcc (5.2V)
Enable Threshold= 1.2V
Enable
SS
Fig. 3. Normal Start up, device turns on
when the bus voltage reaches 10.2V
Figure 4a. shows the recommended start-up
sequence for the normal (non-tracking, nonsequencing) operation of IR3838, when Enable is
used as a logic input. In this operating mode Vref
is left floating. Figure 4b. shows the
recommended startup sequence for sequenced
operation of IR3838 with Enable used as logic
input. For this mode of operation, Vref is left
floating. Figure 4c shows the recommended
startup sequence for tracking operation of
IR3838 with Enable used as logic input. For this
mode of operation, Vref is connected to a voltage
greater than 1.5V.
12
IR3838MPbF
Vref
This pin reflects the internal reference voltage
which is used by the error amplifier to set the
output voltage. In most operating conditions this
pin is only connected to an external bypass
capacitor and it is left floating. In tracking mode
this pin should be connected to an external
voltage greater than 1.5V and less than 7V. For
margining applications, an external voltage
source is connected to Vref pin and overrides
the internal reference voltage. The external
voltage source should have a low internal
resistance (<100Ω) and be able to source and
sink more than 25µA.
Fig. 4a. Recommended startup for
Normal operation
Pvin (12V)
Vcc (5.2V)
Enable > 1. 2 V
SS
Vp
Pre-Bias Startup
IR3838 is able to start up into pre-charged
output, which prevents oscillation and
disturbances of the output voltage.
The output starts in asynchronous fashion and
keeps the synchronous MOSFET (sync FET)
off until the first gate signal for control MOSFET
(control FET) is generated. Figure 5a shows a
typical Pre-Bias condition at start up. The sync
FET always starts with a narrow pulse width
and gradually increases its duty cycle with a
step of 25%, 50%, 75% and 100% until it
reaches the steady state value. The number of
these startup pulses for the sync FET is
internally programmed. Figure 5b shows a
series of 32, 16, 8 startup pulses.
Fig. 4b. Recommended startup for sequencing
operation (ratiometric or simultaneous)
Fig. 5a. Pre-Bias startup
Fig. 4c. Recommended startup for memory
tracking operation (Vtt-DDR)
Rev 1.41
Fig. 5b. Pre-Bias startup pulses
13
IR3838MPbF
Soft-Start
The IR3838 has a digital internal soft-start to
control the output voltage rise and to limit the
current surge at the start-up. To ensure correct
start-up, the soft-start sequence initiates when
the Enable and Vcc rise above their UVLO
thresholds and generate the Power On Ready
(POR) signal. The internal SS signal linearly
rises with the rate of 0.2mV / µs from 0V to 2V.
Figure 6 shows the waveforms during soft start
(also refer to figure 11). The normal start up time
is fixed, and is equal to:
Tstart 
1.3V - 0.7V   3ms
0.2mV/s
- - - - - - - - - - - - - - (1)
During the soft start the OCP is enabled to
protect the device for any short circuit and over
current condition.
Table 1. Switching Frequency and IOCSet vs.
External Resistor (Rt)
Rt (kΩ)
47.5
35.7
28.7
23.7
20.5
17.8
15.8
14.3
12.7
11.5
10.7
9.76
9.31
F s (kHz)
300
400
500
600
700
800
900
1000
1100
1200
1300
1400
1500
I ocset (μA)
14.7
19.6
24.35
29.54
34.1
39.3
44.3
48.95
55.1
60.85
65.4
71.7
75.15
Over-Current Protection
The over current protection is performed by
sensing current through the RDS(on) of the sync
FET. This method enhances the converter’s
efficiency and reduces cost by eliminating a
current sense resistor. As shown in figure 7, an
external resistor (ROCSet) is connected between
OCSet pin and the switch node (SW) which sets
the current limit set point.
An internal current source sources current
(IOCSet ) out of the OCSet pin. This current is a
function of Rt and hence, of the free-running
switching frequency.
I OCSet ( μA) 
Fig. 6. Theoretical operation waveforms
during soft-start (non tracking / non sequencing)
Operating Frequency
The switching frequency can be programmed
between 250kHz – 1500kHz by connecting an
external resistor from Rt pin to Gnd. Table 1
tabulates the oscillator frequency versus Rt.
Shutdown
The IR3838 can be shutdown by pulling the
Enable pin below its 0.85 V threshold. This will
tri-state both, the high side driver as well as the
low side driver.
Rev 1.41
700
.......... .......... .......... .....(2)
Rt (k)
Table 1. shows IOCSet at different switching
frequencies. The internal current source
develops a voltage across ROCSet. When the sync
FET is turned on, the inductor current flows
through Q2 and results in a voltage at OCSet
which is given by:
VOCSet  ( IOCSet  ROCSet )  ( RDS (on)  I L ) ...........(3)
An over current is detected if the OCSet pin goes
below ground. However, to avoid false tripping ,
due to the noise generated when the sync FET is
turned on, the OCP comparator is enabled about
200ns after sync-FET is turned on.
14
IR3838MPbF
External Synchronization
The IR3838 incorporates an internal circuit which
enables synchronization of the internal oscillator
(using rising edge) to an external clock. An
external resistor from Rt pin to Gnd is still
required to set the free-running frequency close
to the Sync input frequency. This function is
important to avoid sub-harmonic oscillations due
to beat frequency for embedded systems when
multiple POL (point of load) regulators are used.
Applying the external signal to the Sync input
changes the effective value of the ramp signal
(Vramp/Vosc).
Vosc1  1.8  f Free_ Run f Sync ........................(5)
Fig. 7. Connection of over current sensing resistor
As mentioned earlier, an over current is detected
if the OCSet pin goes below ground. Hence, at
the current limit threshold, VOCset=0. Then, for a
current limit setting ILimit, ROCSet is calculated as
follows:
ROCSet 
R
DS (on)
* I Limit
IOCSet
........................ (4)
An over-current detection trips the OCP
comparator, latches OCP signal and cycles the
soft start function in hiccup mode.
The hiccup is performed by making the internal
SS signal equal to zero and counting the number
of switching cycles. The Soft Start pin is held low
until 4096 cycles have been completed. The
OCP signal resets and the converter recovers.
After every soft start cycle, the converter stays in
this mode until the overload or short circuit is
removed.
An optional 10pF-22pF filter capacitor can be
connected from OCSet pin to PGnd. It is
recommended to use this capacitor for very
narrow duty cycle applications (pulse-width
<150ns).
Thermal Shutdown
Temperature sensing is provided inside IR3838.
The trip threshold is typically set to 140oC. When
trip threshold is exceeded, thermal shutdown
turns off both MOSFETs and resets the internal
soft start.
Automatic restart is initiated when the sensed
temperature drops within the operating range.
There is a 20oC hysteresis in the thermal
shutdown threshold.
Rev 1.41
Equation (5) shows that the effective amplitude of
the ramp is reduced after the external Sync
signal is applied. More difference between the
frequency of the Sync and the free-running
frequency results in more change in the effective
amplitude of the ramp signal. Therefore, since
the ramp amplitude takes part in calculating the
loop-gain and bandwidth of the regulator, it is
recommended to not use a Sync frequency which
is much higher than the free-running frequency
(or vice versa). In addition, the effective value of
the ramp signal, given by equation (5), should be
used when the compensator is designed for the
regulator.
The pulse width of the external clock, which is
applied to the sync, should be greater than 100ns
and its high level should be greater than 2V,
while its lower level is less than 0.6V. For more
information refer to the Oscillator section in page6. If this pin is left floating, the IC will run with the
free running frequency set by the resistor Rt.
Output Voltage Tracking and Sequencing
The
IR3838
can
accommodate
user
programmable tracking and/or sequencing
options using Vp, Vref, Enable, and Power Good
pins. In the block diagram presented on page 3,
the error-amplifier (E/A) has been depicted with
three positive inputs. Ideally, the input with the
lower voltage is used for regulating the output
voltage and the other two inputs are ignored. In
practice the voltage of the other two inputs
should be about 200mV greater than the lowvoltage input so that their effects can completely
be ignored. For normal operation, Vp is tied to
Vcc (1.5V < Vp < Vcc) and Vref is left floating
(with a bypass capacitor).
15
IR3838MPbF
Therefore, in normal operating condition, after
Enable goes high the SS ramps up the output
voltage until Vfb (voltage of feedback/Fb pin)
reaches about 0.6V. Then Vref takes over and
the output voltage is regulated (refer to Fig. 11).
Tracking-mode operation is achieved by
connecting Vref to Vcc (1.5V<Vref<Vcc). Then,
while Vp=0, Enable is taken above its threshold
so that the soft start circuit generates internal SS
signal. After the internal SS signal reaches the
final value (refer to Fig. 4c) ramping up the Vp
input will ramp up the output voltage. In tracking
mode, Vfb always follows Vp which means Vout
is always proportional to Vp voltage (typical for
DDR/Vtt rail applications)
In sequencing mode of operation (simultaneous
or ratiometric), Vref is left floating and Vp is kept
to ground level until after SS signal reaches the
final value. Then Vp is ramped up and Vfb
follows Vp. When Vp>0.6V the error-amplifier
switches to Vref and the output voltage is
regulated with Vref.
Tracking and sequencing operations can be
implemented to be simultaneous or ratiometric
(refer to figures 9 and 10). Figure 8 shows typical
circuit configuration for sequencing operation.
With this power-up configuration, the voltage at
the Vp pin of the slave reaches 0.6V before the
Fb pin of the master. If RE/RF =RC/RD,
simultaneous startup is achieved. That is, the
output voltage of the slave follows that of the
master until the voltage at the Vp pin of the slave
reaches 0.6 V. After the voltage at the Vp pin of
the slave exceeds 0.6V, the internal
0.6V
reference of the slave dictates its output voltage.
In reality the regulation gradually shifts from Vp
to internal Vref. The circuit shown in Fig. 8 can
also be used for simultaneous or ratiometric
tracking operation if Vref of the slave is
connected to Vcc. Table 2 on page 17
summarizes the required conditions to achieve
simultaneous / ratiometric tracking or sequencing
operations.
Fig. 9 Typical waveforms for sequencing mode
of operation: (a) simultaneous, (b) ratiometric
Fig. 8. Application Circuit for Simultaneous
and ratiometric Sequencing
Rev 1.41
Fig. 10 Typical waveforms in tracking mode of
operation: (a) simultaneous, (b) ratiometric
16
IR3838MPbF
Power Good Output
The IC continually monitors the output voltage via
Feedback (Fb pin). The feedback voltage is
compared to a threshold. The threshold is set
differently at different operating modes and the
results of the comparison sets the PGood signal.
Figures 11, 12, and 13 show the timing diagram
of the PGood signal at different operating modes.
The PGood pin is open drain and it needs to be
externally pulled high. High state indicates that
output is in regulation.
Table 2. The required conditions to achieve simultaneous / ratiometric tracking and sequencing
operations with the circuit configuration of Fig. 8
Operating Mode
Vref (slave)
Vp
Required Condition
Normal (Non-Sequencing,
Non-Tracking)
0.6V (Float)
> 1.5V
-
Simultaneous Sequencing
0.6V
Ramp up from 0V
RA/RB > RE/RF =RC/RD
Ratiometric Sequencing
0.6V
Ramp up from 0V
RA/RB >RE/RF > RC/RD
Simultaneous Tracking
> 1.5V
Ramp up from 0V
RE/RF =RC/RD
Ratiometric Tracking
> 1.5V
Ramp up from 0V
RE/RF >RC/RD
TIMING DIAGRAM OF PGOOD FUNCTIONS
Vref
0.6V
0
2.0V
1.3V
0.7V
SSOK
Internal SS
0
1.15*Vref
Fb
0.85*Vref
0
PGood
0
256/Fs
256/Fs
Fig.11 Non-sequence Startup and Vref Margin (Vp =Vcc)
Rev 1.41
17
IR3838MPbF
TIMING DIAGRAM OF PGOOD FUNCTIONS
Fig.12 Vp Tracking (Vref >1.5V, SS=H)
Fig.13 Vp Sequence and Vref Margin
Rev 1.41
18
IR3838MPbF
Minimum on time Considerations
Maximum Duty Ratio Considerations
The minimum ON time is the shortest amount of
time for which the Control FET may be reliably
turned on, and this depends on the internal
timing delays. For the IR3838, the typical
minimum on-time is specified as 70 ns.
Any design or application using the IR3838 must
ensure operation with a pulse width that is higher
than this minimum on-time and preferably higher
than 150 ns. This is necessary for the circuit to
operate without jitter and pulse-skipping, which
can cause high inductor current ripple and high
output voltage ripple.
A fixed off-time of 300 ns maximum is specified
for the IR3838. This provides an upper limit on
the operating duty ratio at any given switching
frequency. Thus, the higher the switching
frequency, the lower is the maximum duty ratio at
which the IR3838 can operate. To allow some
margin, the maximum operating duty ratio in any
application using the IR3838 should still
accommodate about 500 ns off-time. Fig 14.
shows a plot of the maximum duty ratio v/s the
switching frequency, with 300 ns off-time.
Vout
D

Fs Vin  Fs
In any application that uses the IR3838, the
following condition must be satisfied:
t on(min)  t on
 t on(min) 
Vout
Vin  Fs
Vin  Fs 
Vout
t on(min)
The minimum output voltage is limited by the
reference voltage and hence Vout(min) = 0.6 V.
Therefore, for Vout(min) = 0.6 V,
 Vin  Fs 
95
90
Max Duty Cycle (%)
t on 
85
80
75
70
65
60
55
50
250
450
650
850
1050
1250
1450
1650
Switching Frequency (kHz)
Fig. 14. Maximum duty cycle v/s switching
frequency.
Vout (min)
 Vin  Fs 
t on(min)
0.6 V
 4  10 6 V/s
150 ns
Therefore, at the maximum recommended input
voltage 16V and minimum output voltage, the
converter should be designed at a switching
frequency that does not exceed 250 kHz.
Conversely, for operation at the maximum
recommended operating frequency (1.65 MHz)
and minimum output voltage (0.6V), The input
voltage (PVin) should not exceed 2.42V,
otherwise pulse skipping will happen.
At low output voltages (below 1V) specially at
Vo=0.6V, it is recommended to design the
compensator so that the bandwidth of the loop
does not exceed 1/10 of the switching frequency.
Rev 1.41
19
IR3838MPbF
Application Information
Design Example:
The following example is a typical application for
IR3838. The application circuit is shown on page
26.
Vin = 12 V ( 13.2V max)
Vo = 1.8 V
I o = 10 A
ΔVo ≤  2% ︵
Vo for 30% load transient)
Fs = 600 kHz
 R 
Vo  Vref  1 8  ...................................(8)
 R9 
When an external resistor divider is connected to
the output as shown in figure 16.
Equation (8) can be rewritten as:
 Vref
R9  R8  
 V oVref


 .................................. (9)


For the calculated values of R8
feedback compensation section.
and R9 see
VOUT
Enabling the IR3838
As explained earlier, the precise threshold of
the Enable lends itself well to implementation of
a UVLO for the Bus Voltage as shown in figure
15.
IR3838
IR3624
R8
Fb
R9
V in
IR3838
Enable
R1
R2
Fig. 15. Using Enable pin for UVLO
implementation
For a typical Enable threshold of VEN = 1.2 V
Vin(min) *
R2
 VEN  1.2 .......... (6)
R1  R2
R2  R1
VEN
.......... (7)
Vin( min )  VEN
For a Vin (min)=10.2V, R1=49.9K and R2=6.8k ohm
is a good choice.
Programming the frequency
For Fs = 600 kHz, select Rt = 23.7 kΩ, using
Table 1.
Output Voltage Programming
Output voltage is programmed by reference
voltage and external voltage divider. The Fb pin
is the inverting input of the error amplifier, which
is internally referenced to 0.6V. The divider ratio
is set to provide 0.6V at the Fb pin when the
output is at its desired value. The output voltage
is defined by using the following equation:
Rev 1.41
Fig. 16. Typical application of the IR3838 for
programming the output voltage
Bootstrap Capacitor Selection
To drive the Control FET, it is necessary to
supply a gate voltage at least 4V greater than
the voltage at the SW pin, which is connected to
the source of the Control FET . This is achieved
by using a bootstrap configuration, which
comprises the internal bootstrap diode and an
external bootstrap capacitor (C6). The operation
of the circuit is as follows: When the sync FET is
turned on, the capacitor node connected to SW
is pulled down to ground. The capacitor charges
towards Vcc through the internal bootstrap diode
(figure 17), which has a forward voltage drop VD.
The voltage Vc across the bootstrap capacitor
C6 is approximately given as
Vc  Vcc  VD .......................... (10)
When the control FET turns on in the next cycle,
the capacitor node connected to SW rises to the
bus voltage Vin. However, if the value of C6 is
appropriately chosen, the voltage Vc across C6
remains approximately unchanged and the
voltage at the Boot pin becomes:
VBoot  Vin  Vcc  VD ........................................ (11)
20
IR3838MPbF
Inductor Selection
The inductor is selected based on output power,
operating frequency and efficiency requirements.
A low inductor value causes large ripple current,
resulting in the smaller size, faster response to a
load transient but poor efficiency and high output
noise. Generally, the selection of the inductor
value can be reduced to the desired maximum
ripple current in the inductor (i ) . The optimum
point is usually found between 20% and 50%
ripple of the output current.
For the buck converter, the inductor value for the
desired operating ripple current can be
determined using the following relation:
Fig. 17. Bootstrap circuit to generate
Vc voltage
A bootstrap capacitor of value 0.1uF is suitable
for most applications.
Input Capacitor Selection
The ripple current generated during the on time of
the control FET should be provided by the input
capacitor. The RMS value of this ripple is
expressed by:
i
1
; t  D 
t
Fs
............................... (14)
Vo
L  Vin  Vo  
Vin  i * Fs
Vin  Vo  L 
Where:
Vin  Maximum input voltage
Vo  Output Voltage
Δi  Inductor ripple current
F s  Switching frequency
Δt  Turn on time
D  Duty cycle
I RMS  Io  D(1 D ) ........................(12)
D
Vo
................................ (13)
Vin
Where:
D is the Duty Cycle
IRMS is the RMS value of the input capacitor
current.
Io is the output current.
For Io=10A and D = 0.15, the IRMS = 3.6A.
Ceramic capacitors are recommended due to
their peak current capabilities. They also feature
low ESR and ESL at higher frequency which
enables better efficiency. For this application, it is
advisable to have 3x10uF, 16V ceramic
capacitors, ECJ-3YX1C106K from Panasonic. In
addition to these, although not mandatory, a
1x330uF, 25V SMD capacitor EEV-FK1E331P
may also be used as a bulk capacitor and is
recommended if the input power supply is not
located close to the converter.
Rev 1.41
If Δi ≈ 42.5%(Io), then the output inductor is
calculated to be 0.6μH. Select MPL104-0R6 from
Delta (L=0.6μH) which provides a compact, low
profile inductor suitable for this application.
Output Capacitor Selection
The voltage ripple and transient requirements
determine the output capacitors type and values.
The criteria is normally based on the value of the
Effective Series Resistance (ESR). However the
actual capacitance value and the Equivalent
Series Inductance (ESL) are other contributing
components. These components can be
described as
Vo  Vo( ESR )  Vo( ESL )  Vo( C )
Vo( ESR )  I L * ESR
 V  Vo 
Vo( ESL )   in
 * ESL
 L 
Vo( C ) 
I L
8* Co * Fs
......................... (15)
21
IR3838MPbF
Where:
∆Vo = output voltage ripple
∆IL = Inductor ripple current
Since the output capacitor has a major role in the
overall performance of the converter and
determines the result of transient response,
selection of the capacitor is critical. The IR3838
can perform well with all types of capacitors.
As a rule, the capacitor must have low enough
ESR to meet output ripple and load transient
requirements.
The goal for this design is to meet the voltage
ripple requirement in the smallest possible
capacitor size. Therefore it is advisable to select
ceramic capacitors due to their low ESR and ESL
and small size. Five of Taiyo Yuden’s
JMK212BJ476MG-T (47uF, 6.3V, ≈3mΩ)
capacitors is a good choice.
It is also recommended to use a 0.1µF ceramic
capacitor at the output for high frequency
filtering.
Feedback Compensation
The IR3838 is a voltage mode controller. The
control loop is a single voltage feedback path
including error amplifier and error comparator. To
achieve fast transient response and accurate
output regulation, a compensation circuit is
necessary. The goal of the compensation
network is to provide a closed-loop transfer
function with the highest 0 dB crossing frequency
and adequate phase margin (greater than 45o).
The output LC filter introduces a double pole,
–40dB/decade gain slope above its corner
resonant frequency, and a total phase lag of 180o
(see figure 18). The resonant frequency of the LC
filter is expressed as follows:
FLC 
1
2  π Lo  Co
Fig. 18. Gain and Phase of LC filter
The IR3838 uses a voltage-type error amplifier
with high-gain (110dB) and high-bandwidth
(30MHz). The output of the amplifier is available
for DC gain control and AC phase compensation.
The error amplifier can be compensated either in
type II or type III compensation.
Local feedback with Type II compensation is
shown in Fig. 19.
This method requires that the output capacitor
should have enough ESR to satisfy stability
requirements. If the output capacitor’s ESR
generates a zero at 5kHz to 50kHz, the zero
generates acceptable phase margin and the
Type II compensator can be used.
The ESR zero of the output capacitor is
expressed as follows:
FESR 
1
........................... (17)
2  π*ESR*Co
................................ (16)
Figure 18 shows gain and phase of the LC filter.
Since we already have 180o phase shift from the
output filter alone, the system runs the risk of
being unstable.
Fig. 19. Type II compensation network
and its asymptotic gain plot
Rev 1.41
22
IR3838MPbF
The transfer function (Ve/Vout) is given by:
Zf
1 sR3C4
Ve
.....(18)
 H( s )  

Vout
ZIN
sR8C4
The (s) indicates that the transfer function varies
as a function of frequency. This configuration
introduces a gain and zero, expressed by:
R
Hs  3 ......................................(19)
R8
Fz 
1
............................(20)
2π* R3 * C4
First select the desired zero-crossover frequency
(Fo):
Fo  FESR and Fo  1/5~ 1/10* Fs .......(21)
Use the following equation to calculate R3:
R3 
The additional pole is given by:
FP 
1
.................................(24)
C *C
2π* R3 * 4 POLE
C4  CPOLE
The pole sets to one half of the switching
frequency which results in the capacitor CPOLE:
CPOLE 
1
π*R3*Fs 
For a general solution for unconditional stability
for any type of output capacitors, and a wide
range of ESR values, we should implement local
feedback with a type III compensation network.
The typically used compensation network for
voltage-mode controller is shown in figure 20.
VOUT
ZIN
Vosc * Fo * FESR* R8
...........................(22)
2
Vin * FLC
C7
To cancel one of the LC filter poles, place the
zero before the LC filter resonant frequency pole:
Fz  75% FLC
Fz  0.75*
1
2π Lo * Co
.....................................(23)
Use equations (20), (21) and (22) to calculate
C4.
One more capacitor is sometimes added in
parallel with C4 and R3. This introduces one
more pole which is mainly used to suppress the
switching noise.
Rev 1.41
C3
R3
R8
R10
Where:
Vin = Maximum Input Voltage
Vosc = Amplitude of the oscillator Ramp Voltage
Fo = Crossover Frequency
FESR = Zero Frequency of the Output Capacitor
FLC = Resonant Frequency of the Output Filter
R8 = Feedback Resistor
1
C4
1
...................... (25)
π*R3*Fs

C4
Zf
Fb
R9
E/A
Ve
Comp
VREF
Gain (dB)
|H(s)| dB
FZ1
FZ 2
FP2
FP3
Frequency
Fig.20. Type III Compensation network and
its asymptotic gain plot
23
IR3838MPbF
Again, the transfer function is given by:
Zf
Ve
 H( s )  
Vout
Z IN
By replacing Zin and Zf according to figure 20,
the transfer function can be expressed as:

H( s ) 
( 1 sR3C4 )1 sC7 R8  R10 

 C * C 
sR8 ( C4  C3 )1 sR3  4 3 ( 1 sR10C7 )

 C4  C3 
.... (26)
The compensation network has three poles and
two zeros and they are expressed as follows:
FP1  0 ..................................................................(27)
FP2 
1
...............................................(28)
2π * R10 * C7
1
1

...............(29)
 C4 * C3  2π * R3 * C3

2π * R3 
 C4  C3 
1
FZ1 
.............................................(30)
2π * R3 * C4
FP3 
FZ 2 
1
1

..........(31)
2π * C7 * ( R8  R10 ) 2π * C7 * R8
Cross over frequency is expressed as:
Fo  R3 * C7 *
Vin
1
*
................................ (32)
Vosc 2π* Lo * Co
Based on the frequency of the zero generated by
the output capacitor and its ESR, relative to
crossover frequency, the compensation type can
be different. Table 3 shows the compensation
types for relative locations of the crossover
frequency.
Rev 1.41
Table 3. Different types of compensators
Compensator
Type
Type II
Type III
F ESR vs F 0
F LC < F ESR < F 0 < F S /2
F LC < F 0 < F ESR
Typical Output
Capacitor
Electrolytic
SP-Cap, Ceramic
The higher the crossover frequency is, the
potentially faster the load transient response will
be. However, the crossover frequency should be
low enough to allow attenuation of switching
noise. Typically, the control loop bandwidth or
crossover frequency (Fo) is selected such that
Fo  1/5 ~ 1/10 * Fs
The DC gain should be large enough to provide
high DC-regulation accuracy. The phase margin
should be greater than 45o for overall stability.
For this design we have:
Vin=12V
Vo=1.8V
Vosc=1.8V
Vref=0.6V
Lo=0.6µH
Co=5x47µF, ESR≈3mΩ each
It must be noted here that the value of the
capacitance used in the compensator design
must be the small signal value. For instance, the
small signal capacitance of the 47uF capacitor
used in this design is 26uF at 1.8 V DC bias and
600 kHz frequency. It is this value that must be
used for all computations related to the
compensation. The small signal value may be
obtained from the manufacturer’s datasheets,
design tools or SPICE models. Alternatively, they
may also be inferred from measuring the power
stage transfer function of the converter and
measuring the double pole frequency FLC and
using equation (16) to compute the small signal
Co.
These result to:
FLC=18 kHz
FESR=2.04 MHz
Fs/2=300 kHz
24
IR3838MPbF
Select crossover frequency F0=100 kHz
Since FLC<F0<Fs/2<FESR, Type III is selected to
place the pole and zeros.
Detailed calculation of compensation Type III :
Desired Phase Margin   70o
FZ 2  Fo
1 sin 
 17.63kHz
1 sin 
1 sin 
FP2  Fo
 567.1kHz
1 sin 
Programming the Current-Limit
The Current-Limit threshold can be set by
connecting a resistor (ROCSet) from the SW pin
to the OCSet pin. The resistor can be calculated
by using equation (4). This resistor (ROCSet) must
be placed close to the IC.
The RDS(on) has a positive temperature
coefficient and it should be considered for the
worst case operation (40% increase due to
temperature has been considered in below).
I SET  I L( critical) 
ROCSet IOCSet
.......................(33)
RDS( on)
RDS ( on )  8.5 mΩ *1.4  11.9 mΩ
Select: FZ1  0.5* FZ 2  8.82 kHz and
FP3  0.5* Fs  300 kHz
Select: C7  2.2nF
Calculate R3 , C3 and C4 :
R3 
2π* Fo * Lo * Co *Vosc
; R3  3.34 kΩ
C7 *Vin
Select: R3  3.32 k
C4 
1
; C4  5.44 nF, Select: C4  5.6 nF
2π * FZ1 * R 3
C3 
1
; C3  159 pF, Select: C3  150 pF
2π* FP3 * R3
Calculate R10 , R8 and R9 :
R10 
R8 
1
; R10  128 Ω, Select: R10  127 Ω
2π* C7 * FP2
1
- R10; R8  3.98 kΩ,
2π* C7 * FZ 2
Select: R8  4.02 kΩ
R9 
Vref
Vo -Vref
I SET  I o( LIM )  10 A *1.5  15 A
(50% over nominal
output current )
I OCSet  29.54 μA (at Fs  600 kHz)
R OCSet  6.04 kΩ Select R OCSet  6.04 kΩ
The optional filter capacitor from OCSet pin to
PGnd has not been used for this design.
Setting the Power Good Threshold
In this design IR3838 is used in normal (nontracking, non-sequencing) mode, therefore the
PGood thresholds are internally set at 85% and
115% of Vref. At startup as soon as the internal
soft start signal reaches 2V (Figure 11), and
assuming Fb voltage follows Vref, the PGood is
asserted. As long as the voltage at the Fb pin is
between the thresholds (mentioned above),
Enable is high, and no fault happens, the PGood
remains high.
The PGood is an open drain output. Hence, it is
necessary to use a pull up resistor, RPG, from
PGood pin to Vcc. The value of the pull-up
resistor must be chosen such as to limit the
current flowing into the PGood pin to less than
5mA when the output voltage is not in regulation.
A typical value used is 10kΩ.
Vref Bypass Capacitor
A bypass capacitor of about 0.1uF is required to
be placed between Vref and Gnd pins. This
capacitor should be placed as close as possible
to Vref pin.
* R8 ; R9  2.01 kΩ Select: R9  2 kΩ
Rev 1.41
25
IR3838MPbF
Application Diagram:
Fig. 21. Application circuit diagram for a 12V to 1.8 V, 10 A Point Of Load Converter
Suggested Bill of Materials for the application circuit:
Part Reference
Description
Manufacturer
Part Number
1 330uF
SMD Elecrolytic, Fsize, 25V, 20%
Panasonic
EEV-FK1E331P
3 10uF
1206, 16V, X7R, 20%
Panasonic - ECG
ECJ-3YX1C106K
Lo
1 0.6uH
11.5x10x4mm, 20%, 1.5mΩ
Delta
MPL104-0R6
Co
5 47uF
Ceramic, 6.3V, 0805, X5R,20%
Taiyo Yuden
JMK212BJ476MG-T
R1
1 49.9K
Thick Film, 0603,1/10 W,1%
Rohm
MCR03EZPFX4992
R2
1 6.8K
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX6801
Rt
1 23.7k
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX2372
ROCSet
1 6.04k
Thick Film, 0603,1/10 W,1%
Rohm
MCR03EZPFX6041
RPG
1 10K
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX1002
Cref
1 0.1uF
0603, 25V, X7R, 10%
Panasonic - ECG
ECJ-1VB1E104K
R3
1 3.32k
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX3321
C3
1 150pF
50V, 0603, NPO, 5%
Panasonic- ECG
ECJ-1VC1H151J
C4
1 5.6nF
0603, 50V, X7R, 10%
Panasonic - ECG
ECJ-1VB1H562K
C6
1 0.1uF
0603, 25V, X7R, 10%
Panasonic - ECG
ECJ-1VB1E104K
R8
1 4.02K
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX4021
R9
1 2.0K
Thick Film, 0603,1/10W,1%
Rohm
MCR03EZPFX2001
R10
1 127
Thick Film, 0603,1/10W,1%
Panasonic - ECG
ERJ-3EKF1270V
C7
1 2200pF
0603, 50V, X7R, 10%
Panasonic - ECG
ECJ-1VB1H222K
CVcc
1 2.2uF
0603, 10V, X5R, 10%
Panasonic - ECG
ECJ-1VB1A225K
U1
1 IR3838
SupIRBuck, 10A, PQFN 5x6mm
International Rectifier
IR3838MPbF
Cin
Rev 1.41
Quantity
Value
26
IR3838MPbF
TYPICAL OPERATING WAVEFORMS
Vin=12V, Vcc/LDO=5.2V, Vo=1.8V, Io=0-10A, Room Temperature, No Air Flow
Fig. 22: Start up at 10A Load (Note 6)
Ch1:Vout Ch2:PGood Ch3:EN Ch4: Vin
Fig. 24: Start up with 1.62V Prebias,
0A Load, Ch1:Vout Ch2: PGood Ch3: EN
Fig. 26: Inductor node at 10A load
Ch3:SW
Rev 1.41
Fig. 23: Start up at 10A Load (Note 6)
Ch1:Vout Ch2:PGood Ch3:Vcc Ch4: Vin
Fig. 25: Output Voltage Ripple,
10A load Ch1: Vout
Fig. 27: Short (Hiccup) Recovery
Ch1:Vout, Ch2:PGood , Ch4:Iout
27
IR3838MPbF
TYPICAL OPERATING WAVEFORMS
Vin=12V, Vcc/LDO=5.2V, Vo=1.8V, Room Temperature, No Air Flow
Fig. 28: Transient Response
1A-4A load (0.5A/us) Ch1:Vout, Ch4:Io
Note6: Enable (EN) is tied to Vin via a resistor divider and triggered when Vin is exceeding above 10.2V.
Rev 1.41
28
IR3838MPbF
TYPICAL OPERATING WAVEFORMS
Vin=12V, Vcc/LDO=5.2V, Vo=1.8V, Io=0-10A, Room Temperature, No Air Flow
Fig.29: Bode Plot at 10A load shows a bandwidth of 94kHz and phase margin of 51 degrees
Rev 1.41
29
IR3838MPbF
Layout Considerations
The layout is very important when designing high
frequency switching converters. Layout will affect
noise pickup and can cause a good design to
perform with less than expected results.
Make all the connections for the power
components in the top layer with wide, copper
filled areas or polygons. In general, it is desirable
to make proper use of power planes and
polygons for power distribution and heat
dissipation.
The inductor, output capacitors and the IR3838
should be as close to each other as possible.
This helps to reduce the EMI radiated by the
power traces due to the high switching currents
through them. Place the input capacitor directly at
the PVin pin of IR3838.
The feedback part of the system should be kept
away from the inductor and other noise sources.
The critical bypass components such as
capacitors for Vin, Vcc, Vref and Vp should be
close to their respective pins. It is important to
place the feedback components including
feedback
resistors
and
compensation
components close to Fb and Comp pins.
The connection between the OCSet resistor and
the SW pin should not share any trace with the
connection between the bootstrap capacitor and
the SW pin. Instead, it is recommended to use a
Kelvin connection of the trace from the OCSet
resistor and the trace from the bootstrap
Vin
capacitor at the SW pin. PGnd
Also, place the OCset
resistor close to the device.
In a multilayer PCB use one layer as a power
ground plane and have a control circuit ground
(analog ground), to which all signals are
referenced. The goal is to localize the high
AGnd
current
path to a separateVout
loop that does not
interfere with the more sensitive analog control
function. These two grounds must be connected
together on the PC board layout at a single point.
It is recommended to place all the compensation
parts over the analog ground plane in top layer.
The Power QFN is a thermally enhanced
package. Based on thermal performance it is
recommended to use at least a 4-layers PCB. To
effectively remove heat from the device the
exposed pad should be connected to the ground
plane using vias. Figure 30 illustrates the
implementation of the layout guidelines outlined
above, on the IRDC3838 4 layer demoboard.
Vin
PGnd
Vout
AGnd
Enough copper &
minimum length
ground path between
Input and Output
AGnd
PGnd
Vin
Compensation parts
should be placed as
close as possible to
the Comp pin.
Resistors Rt and
ROCSet should be
placed as close as
possible to their pins.
All bypass caps
should be placed as
close as possible to
their connecting
pins.
Vout
PGnd
Fig. 30a. IRDC3838 Demoboard layout
considerations – Top Layer
Rev 1.41
30
IR3838MPbF
Boot cap uses separate
trace from ROCSet to be
connected to SW node
PGnd
Fig. 30b. IRDC3838 demoboard layout
considerations – Bottom Layer
Power Ground plane
Analog Ground plane
Feedback trace
should be kept
away form noise
sources
Single point connection
between AGND &
PGND, should be close
to the SupIRBuck, kept
away from noise
sources.
Fig. 30c. IRDC3838 demoboard layout
considerations – Mid Layer 1
The trace which
connects ROCSet
to SW node is
separated from
the trace which
connect Boot
Cap to SW node
Fig. 30d. IRDC3838 demoboard layout
considerations – Mid Layer 2
Rev 1.41
31
IR3838MPbF
PCB Metal and Components Placement
Evaluations have shown that the best overall performance is achieved using the substrate/PCB
layout as shown in following figures. PQFN devices should be placed to an accuracy of 0.050mm
on both X and Y axes. Self-centering behavior is highly dependent on solders and processes, and
experiments should be run to confirm the limits of self-centering on specific processes. For further
information, please refer to “SupIRBuck™ Multi-Chip Module (MCM) Power Quad Flat No-Lead
(PQFN) Board Mounting Application Note.” (AN-1132)
PCB metal pad sizing (all dimensions in mm)
PCB metal pad spacing (all dimensions in mm)
Rev 1.41
32
IR3838MPbF
Solder Resist
It is recommended that the lead lands are Non Solder Mask Defined (NSMD). The solder resist should
be pulled away from the metal lead lands by a minimum of 0.025mm to ensure NSMD pads.
The land pad should be Solder Mask Defined (SMD), with a minimum overlap of the solder resist onto
the copper of 0.05mm to accommodate solder resist mis-alignment.
Ensure that the solder resist in between the lead lands and the pad land is ≥ 0.15mm due to the high
aspect ratio of the solder resist strip separating the lead lands from the pad land.
Rev 1.41
33
IR3838MPbF
Stencil Design
Stencils for PQFN can be used with thicknesses of 0.100-0.250mm (0.004-0.010"). Stencils thinner
than 0.100mm are unsuitable because they deposit insufficient solder paste to make good solder
joints with the ground pad; high reductions sometimes create similar problems. Stencils in the
range of 0.125mm-0.200mm (0.005-0.008"), with suitable reductions, give the best results.
Evaluations have shown that the best overall performance is achieved using the stencil design
shown in following figure. This design is for a stencil thickness of 0.127mm (0.005"). The reduction
should be adjusted for stencils of other thicknesses.
Stencil pad sizing (all dimensions in mm)
Stencil pad spacing (all dimensions in mm)
Rev 1.41
34
IR3838MPbF
DIM
A
A1
b
b1
c
D
E
e
e1
e2
MILIMITERS
MIN
MAX
0.800 1.000
0.000 0.050
0.375 0.475
0.250 0.350
0.203 REF.
5.000 BASIC
6.000 BASIC
1.033 BASIC
0.650 BASIC
0.852 BASIC
INCHES
MIN
MAX
0.0315 0.0394
0.0000 0.0020
0.1477 0.1871
0.0098 0.1379
0.008 REF.
1.969 BASIC
2.362 BASIC
0.0407 BASIC
0.0256 BASIC
0.0335 BASIC
DIM
L
M
N
O
P
Q
R
S
t1, t2, t3
t4
t5
MILIMITERS
MIN
MAX
0.350
0.450
2.441
2.541
0.703
0.803
2.079
2.179
3.242
3.342
1.265
1.365
2.644
2.744
1.500
1.600
0.401 BASIC
1.153 BASIC
0.727 BASIC
INCHES
MIN
MAX
0.0138 0.0177
0.0961 0.1000
0.0277 0.0316
0.0819 0.0858
0.1276 0.1316
0.0498 0.0537
0.1041 0.1080
0.0591 0.0630
0.016 BACIS
0.045 BASIC
0.0286 BASIC
IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105
TAC Fax: (310) 252-7903
This product has been designed and qualified for the Industrial market (Note5)
Visit us at www.irf.com for sales contact information
Data and specifications subject to change without notice. 11/11
Rev 1.41
35