SEMTECH SC4603IMSTRT

SC4603
Very Low Input, MHz Operation,
High Efficiency Synchronous Buck
POWER MANAGEMENT
Description
Features
The SC4603 is a voltage mode step down (buck) regulator controller that provides accurate high efficiency power
conversion from input supply range 2.25V to 5.5V. A high
level of integration reduces external component count
and makes it suitable for low voltage applications where
cost, size and efficiency are critical.
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The SC4603 drives external complementary power
MOSFETs; P-channel on the high side and N-channel on
the low side. The use of high side P-channel MOSFETs
eliminates the need for an external charge pump and
simplifies the high side gate driver. Non-overlap protection is provided for the gate drive signals to prevent shoot
through of the MOSFET pair. The voltage drop across the
P-channel MOSFET during its conduction is sensed for
lossless short circuit current limiting.
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BICMOS voltage mode PWM controller
2.25V to 5.5V Input voltage range
Output voltages as low as 0.5V
Sleep mode (Icc = 10µA typ)
Lossless adjustable overcurrent protection
Combination pulse by pulse & hiccup mode current
limit
High efficiency synchronous switching
0% to 100% Duty cycle range
Synchronization to external clock
Asynchronous start-up
1MHz frequency of operation
10-Pin MSOP surface mount package. Lead free
product. This product is fully WEEE and RoHS
compliant
Applications
A low power sleep mode can be achieved by forcing the
SYNC/SLEEP pin below 0.8V. A synchronous mode of operation is activated as the SYNC/SLEEP pin is driven by
an external clock. The quiescent supply current in sleep
mode is typically lower than 10µA. A 1.7ms soft start is
internally provided to prevent output voltage overshoot
during start-up. A 100% maximum duty cycle allows the
SC4603 to operate as a low dropout regulator in the
event of a low battery condition.
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Distributed power architecture
Servers/workstations
Local microprocessor core power supplies
DSP and I/O power supplies
Battery powered applications
Telecommunication equipment
Data processing applications
The SC4603 is an ideal choice for 3.3V, 5V or other low
input supply systems. It’s available in 10 pin MSOP
package.
Typical Application Circuit
Vin = 2.25V ~ 5.5V
R15
1
R3
RT 34.8k
4.7u
C3
1
2
3
C1
R1
20k
150p
4
FS
ISET
VCC
SYNC
COMP
PDRV
PHASE
NDRV
VSENSE
C2
1n
M1
33n
U1
5
C14
GND
C11
C12
C13
22u
22u
22u
22u
6
10
7
R6
L1
1.0
Vout = 1.5V (as low as 0.5V * ) /6A
2.3u
9
M2
8
R5
SC4603
C10
C7
150u
1.0
1
1.2n
22u
* External components can be modified to provide a Vout as low as 0.5V.
Revision: May 16, 2008
C9
C4
R7
14k
R8
806
R9
6.98k
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SC4603
POWER MANAGEMENT
Absolute Maximum Ratings
Exceeding the specifications below may result in permanent damage to the device, or device malfunction. Operation outside of the parameters specified
in the Electrical Characteristics section is not implied.
Parameter
Symbol
Maximum
Units
6
V
Output Drivers (PDRV, NDRV) Currents Continuous
±0.25
A
Inputs (VSENSE, COMP, SYNC/SLEEP, FS, ISET)
6
V
-0.3 to 5.5
V
-2 to 6
V
TA
-40 to +85
°C
Storage Temperature Range
TSTG
-65 to +150
°C
Junction Temperature Range
TJ
-55 to +150
°C
Thermal Impedance Junction to Case
θJ C
41.9
°C/W
Thermal Impedance Junction to Ambient
θJ A
113.1
°C/W
Lead Temperature (Soldering) 10 Sec.
TLEAD
300
°C
ESD Rating (Human Body Model)
ESD
2
kV
Supply Voltage (VCC)
Phase
Phase Pulse tpulse < 50ns
Operating Ambient Temperature Range
Electrical Characteristics
Unless otherwise specified, VCC = 3.3V, RT = 21Kohm, TA = -40°C to 85°C, TA = TJ.
Parameter
All voltages are with respect to GND. Currents are positive into,
negative out of the specified terminal.
Test Conditions
Min
Typ
Max
Unit
5.5
V
10
15
µA
Supply Current, Operating
2
3
mA
VCC Turn-on Threshold
2
2.25
V
VCC Turn-off Hysteresis
100
Overall
Supply Voltage
Supply Current, Sleep
2.25
VSYNC/SLEEP = 0V
mV
Error Amplifier
Internal Reference
Internal Reference Change
VCC = 3.3V, TA = 25°C
495
VCC = 3.3V, TA = -40°C to 85°C
492
VCC = 2.25V to 3.3V, TA = 25°C
-0.15
VCC = 3.3V to 5.5V, TA = 25°C
-0.4
VSENSE Bias Current
Open Loop Gain (1)
VCOMP = 0.5V to 2.5V
Unity Gain Bandwidth (1)
Slew Rate
(1)
 2008 Semtech Corp.
2
80 (1)
500
505
mV
508
mV
0.1
0.35
%/V
-0.2
0
%/V
200
nA
90
dB
8
MHz
2.4
V/µs
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SC4603
POWER MANAGEMENT
Electrical Characteristics (Cont.)
Unless otherwise specified, VCC = 3.3V, RT = 21Kohm, TA = -40°C to 85°C, TA = TJ.
Parameter
Test Conditions
Min
Typ
VCOMP High
ICOMP = -5.5mA
VCC - 0.6
VCC - 0.4
VCOMP Low
ICOMP = 5.5mA
Max
Unit
Error Amplifier (Cont.)
V
0.35
0.525
V
600
660
kHz
Oscillator
Initial Accuracy
TA = 25°C, VSYNC/SLEEP = HIGH
Voltage Stability
TA = 25°C, VCC = 2.25V to 5.5V
1
%/V
TA = -40°C to 85°C
0.01
%/°C
1
MHz
Temperature Coefficient
540
Synchronization Frequency
SYNC Low Threshold
0.8
SYNC High Threshold
2.0
Ramp Peak to Valley (1)
Ramp Peak Voltage
Ramp Valley Voltage
(1)
(1)
V
V
1
V
1.25
V
0.25
V
Sleep, Soft Start, Current Limit
Sleep Threshold
Measured at VSYNC/SLEEP
LOGIC LOW
Measured at VSYNC/SLEEP
LOGIC HIGH
Sleep Input Bias Current (2)
Soft Start Time
(1)
Current Limit Threshold
(2)
0.8
2.0
V
V
VSYNC/SLEEP = 0V
-50
nA
FSW = 600kHz
1.7
ms
Bias Current, TJ = 25°C
Temperature Coefficient
-43
-50
-57
µA
+0.3
%/°C
150
ns
Vcc = 3.3V, IOUT = -100mA (source)
3.4
ohms
Vcc = 3.3V, IOUT = 100mA (sink)
3
ohms
Vcc = 3.3V, IOUT = -100mA (source)
3.4
ohms
Vcc = 3.3V, IOUT = 100mA (sink)
1.5
ohms
Vgs = 3.3V, COUT = 1.0nF
8
ns
Vgs = 3.3V, COUT = 1.0nF
7
ns
Current Limit Blank Time(1)
N-Channel and P-Channel Driver Outputs
Pull Up Resistance (PDRV) (2)
Pull Down Resistance (PDRV) (2)
Pull Up Resistance (NDRV) (1)
Pull Down Resistance (NDRV) (2)
PDRV Output Rise Time
PDRV Output Fall Time
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(2)
(2)
3
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SC4603
POWER MANAGEMENT
Electrical Characteristics (Cont.)
Unless otherwise specified, VCC = 3.3V, RT = 21Kohm, TA = -40°C to 85°C, TA = TJ.
Parameter
Test Conditions
Min
Typ
Max
Unit
N-channel and P-Channel Driver Outputs (Cont.)
NDRV Output Rise Time
NDRV Output Fall Time
(1)
(2)
Vgs = 3.3V, CCOMP = 1nF
8
ns
Vgs = 3.3V, CCOMP = 1nF
3
ns
adaptive
Deadtime Delay
(PDRV high to NDRV high) (3)
30
Deadtime Delay
(NDRV low to PDRV low) (1)
50
ns
Notes:
(1). Guaranteed by design.
(2). Guaranteed by characterization.
(3). Dead time delay from PDRV high to NDRV high is adaptive. As the phase node voltage drops below 600mV due to PDRV
high, NDRV will start to turn high.
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SC4603
POWER MANAGEMENT
Pin Configuration
Ordering Information
Top View
Part Number(1)
Device
SC4603IMSTRT(2)
MSOP-10
Notes:
(1) Only available in tape and reel packaging. A reel
contains 2500 devices.
(2) Lead free product. This product is fully WEEE and
RoHS compliant.
(10 Pin MSOP)
Pin Descriptions
VCC: Positive supply rail for the IC. Bypass this pin to
GND with a 0.1 to 4.7µF low ESL/ESR ceramic capacitor.
PHASE, ISET: PHASE input is connected to the junction
between the two external power MOSFET transistors. The
voltage drop across the upper P-channel device is monitored by PHASE and ISET during PFET conduction and
forms the current limit comparator and logic that sets
the PWM latch and terminates the PFET output pulse
once excessive voltage drop across the PFET is detected.
The controller stops switching and goes through a soft
start sequence once the converter output voltage drops
below 70% its nominal voltage. This prevents excess
power dissipation in the PMOSFET during a short circuit.
The current limit threshold is set by the external resistor
between VCC and ISET. The internal 50µA current source
has a positive temperature coefficient that can compensate PMOSFET Rdson variation due to its junction temperature change.
GND: All voltages are measured with respect to this pin.
All bypass and timing capacitors connected to GND should
have leads as short and direct as possible.
FS: An external resistor connected with FS pin sets the
clock frequency.
SYNC/SLEEP: The oscillator frequency of SC4603 is
set by FS when SYNC/SLEEP is pulled and held above
2V. Its synchronous mode operation is activated as the
SYNC/SLEEP is driven by an external clock. The oscillator and PWM are designed to provide practical operation
to 1MHz when synchronized. Sleep mode is invoked if
SYNC/SLEEP is pulled and held below 0.8V which can be
accomplished by an external gate or transistor. The
Sleepmode supply current is 10µA typical.
PDRV, NDRV: The PWM circuitry provides complementary drive signals to the output stages. The Cross conduction of the external MOSFETs is prevented by monitoring the voltage on the P-channel and N-channel driver
pins in conjunction with a time delay optimized for FET
turn-off characteristics.
VSENSE: This pin is the inverting input of the voltage
amplifier and serves as the output voltage feedback point
for the Buck converter. It senses the output voltage through
an external divider.
COMP: This is the output of the voltage amplifier. The
voltage at this output is connected to the inverting input
of the PWM comparator. A lead-lag network around the
voltage amplifier compensates for the two pole LC filter
characteristic inherent to voltage mode control and is
required in order to optimize the dynamic performance
of the voltage mode control loop.
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SC4603
POWER MANAGEMENT
Typical Characteristics
Oscillator Internal Accuracy
vs
Input Voltage
Oscillator Internal Accuracy
vs
Temperature
Internal Accuracy (kHz)
Internal Accuracy (kHz)
600
595
590
585
TA = 25°C
580
2
2.5
3
3.5
4
4.5
5
5.5
602.0
Vcc = 3.3V
600.0
598.0
596.0
594.0
592.0
-40
-20
0
Vcc (V)
Sense Voltage (mV)
Sense Voltage (mV)
TA = 25°C
2
2.5
3
3.5
4
4.5
5
499.0
-20
0
40
80
Current Limit Bias Current
vs
Temperature
Current Limit Bias
Current (uA)
Current Limit Bias
Current (uA)
20
Temperature (°C)
51
51
50
4
4.5
5
5.5
60
58
56
54
52
50
48
46
44
42
40
38
Vcc = 3.3V
-40
Vcc (V)
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60
Vcc = 3.3V
498.5
-40
52
3.5
80
499.5
5.5
TA = 25°C
3
60
500.0
53
2.5
80
500.5
Current Limit Bias Current
vs
Input Voltage
2
60
501.0
Vcc (V)
52
40
Sense Voltage
vs
Temperature
Sense Voltage
vs
Input Voltage
501.0
500.5
500.0
499.5
499.0
498.5
498.0
497.5
20
Temperature (°C)
-20
0
20
40
Temperature (°C)
6
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SC4603
POWER MANAGEMENT
Block Diagram
Applications Information
Enable
fS =
126 • 10 8
RT
Pulling and holding the SYNC/SLEEP pin below 0.8V initializes the SLEEP mode of the SC4603 with its typical
SLEEP mode supply current of 10uA. During the SLEEP
mode, the high side and low side MOSFETs are turned
off and the internal soft start voltage is held low.
An external clock connected to the SYNC/SLEEP activates its synchronous mode and the frequency of the
clock can be up to 1MHz.
Oscillator
UVLO
The oscillator uses an external resistor to set the oscillation frequency when the SYNC/SLEEP pin is pulled and
held above 2V. The ramp waveform is a triangle at the
PWM frequency with a peak voltage of 1.25V and a valley voltage of 0.25V. A 100% maximum duty cycle allows
the SC4603 to operate as a low dropout regulator in the
event of a low battery condition. The resistor tolerance
adds to the accuracy of the oscillator frequency. The external resistor connected to the FS pin, as shown below
determines the approximate operating frequency:
When the SYNC/SLEEP pin is pulled and held above 2V,
the voltage on the VCC pin determines the operation of
the SC4603. As VCC increases during start up, the UVLO
block senses VCC and keeps the high side and low side
MOSFETs off and the internal soft start voltage low until
VCC reaches 2.25V. If no faults are present, the SC4603
will initiate a soft start when VCC exceeds 2.25V. A
hysteresis (100mV) in the UVLO comparator provides
noise immunity during its start up.
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
IMAX and the internal 50µA pull down current available on
the ISET pin based on the following expression:
Soft Start
The soft start function is required for step down controllers to prevent excess inrush current through the DC bus
during start up. Generally this can be done by sourcing a
controlled current into a timing capacitor and then using
the voltage across this capacitor to slowly ramp up the
error amp reference. The closed loop creates narrow
width driver pulses while the output voltage is low and
allows these pulses to increase to their steady state duty
cycle as the output voltage reaches its regulated value.
With this, the inrush current from the input side is controlled. The duration of the soft start in the SC4603 is
controlled by an internal timing circuit which is used during start up and over current to set the hiccup time. The
soft start time can be calculated by:
TSOFT _ START =
R SET =
IMAX • RDS( ON)
50µA
Kelvin sensing connections should be used at the drain
and source of P-MOSFET.
The RDS(ON) sensing used in the SC4603 has an additional feature that enhances the performance of the over
current protection. Because the RDS(ON) has a positive
temperature coefficient, the 50µA current source has a
positive coefficient of about 0.3%/C° providing first order correction for current sensing vs temperature. This
compensation depends on the high amount of thermal
transferring that typically exists between the high side PMOSFET and the SC4603 due to the compact layout of
the power supply.
1020
fS
When the converter detects an over current condition
(I > IMAX) as shown in Figure 1, the first action the SC4603
takes is to enter cycle by cycle protection mode (Point B
to Point C), which responds to minor over current cases.
Then the output voltage is monitored. If the over current
and low output voltage (set at 70% of nominal output
voltage) occur at the same time, the Hiccup mode operation (Point C to Point D) of the SC4603 is invoked
and the internal soft start capacitor is discharged. This is
like a typical soft start cycle.
As can be seen here, the soft start time is switching
frequency dependant. For example, if f s = 600kHz,
T SOFT_ START = 1020/600k = 1.7ms. But if f s = 1MHz,
TSOFT_START = 1020/1M = 1.02ms.
The SC4603 implements its soft start by ramping up the
error amplifier reference voltage providing a controlled
slew rate of the output voltage, then preventing overshoot and limiting inrush current during its start up..
Over Current Protection
A
Over current protection for the SC4603 is implemented
by detecting the voltage drop of the high side P-MOSFET
during conduction, also known as high side RDS(ON) detection. This loss-less detection eliminates the sense resistor and its loss. The overall efficiency is improved and
the number of components and cost of the converter
are reduced. RDS(ON) sensing is by default inaccurate and
is mainly used to protect the power supply during a fault
case. The over current trigger point will vary from unit to
unit as the RDS(ON) of P-MOSFET varies. Even for the same
unit, the over current trigger point will vary as the junction temperature of P-MOSFET varies. The SC4603 provides a built-in 50µA current source, which is combined
with RSET (connected between VCC and ISET) to determine
the current limit threshold. The value of RSET can be properly selected according to the desired current limit point
 2008 Semtech Corp.
B
VO − nom
0.6875
0.7⋅ VO − nom
C
VO
D
IMA
IO
Figure 1. Over current protection characteristic of
SC4603
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
ripple current to be within 15% to 30% of the maximum
output current.
Power MOSFET Drivers
The inductor value can be determined according to its
operating point and the switching frequency as follows:
The SC4603 has two drivers for external complementary power MOSFETs. The driver block consists of one
high side P-MOSFET driver, PDRV, and one low side NMOSFET driver, NDRV, which are optimized for driving
external power MOSFETs in a synchronous buck converter. The output drivers also have gate drive non-overlap mechanism that gives a dead time between PDRV
and NDRV transitions to avoid potential shoot through
problems in the external MOSFETs. By using the proper
design and the appropriate MOSFETs, a 6A converter can
be achieved. As shown in Figure 2, td1, the delay from
the P-MOSFET off to the N-MOSFET on is adaptive by
detecting the voltage of the phase node. td2, the delay
from the N-MOSFET off to the P-MOSFET on is fixed, is
50ns for the SC4603. This control scheme guarantees
avoiding the cross conduction or shoot through between
two MOSFETs and minimizes the conduction loss in the
bottom diode for high efficiency applications.
L=
Where:
fs = switching frequency and
∆I = ratio of the peak to peak inductor current to the
maximum output load current.
The peak to peak inductor current is:
Ip −p = ∆I • IOMAX
After the required inductor value is selected, the proper
selection of the core material is based on the peak inductor current and efficiency requirements. The core
must be able to handle the peak inductor current IPEAK
without saturation and produce low core loss during the
high frequency operation.
PMOSFET Gate Drive
IPEAK = IOMAX +
NMOSFET Gate Drive
td1
Ip −p
2
The power loss for the inductor includes its core loss and
copper loss. If possible, the winding resistance should
be minimized to reduce inductor’s copper loss. The core
loss can be found in the manufacturer’s datasheet. The
inductor’s copper loss can be estimated as follows:
Ground
Phase node
td2
PCOPPER = I2LRMS ⋅ R WINDING
Figure 2. Timing Waveforms for Gate Drives and Phase Node
Where:
ILRMS is the RMS current in the inductor. This current can
be calculated as follows:
Inductor Selection
The factors for selecting the inductor include its cost,
efficiency, size and EMI. For a typical SC4603 application, the inductor selection is mainly based on its value,
saturation current and DC resistance. Increasing the inductor value will decrease the ripple level of the output
voltage while the output transient response will be degraded. Low value inductors offer small size and fast transient responses while they cause large ripple currents,
poor efficiencies and more output capacitance to smooth
out the large ripple currents. The inductor should be able
to handle the peak current without saturating and its
copper resistance in the winding should be as low as
possible to minimize its resistive power loss. A good tradeoff among its size, loss and cost is to set the inductor
 2008 Semtech Corp.
Vout ⋅ ( Vin − Vout )
Vin ⋅ fs ⋅ ∆I ⋅ IOMAX
ILRMS = IOMAX ⋅ 1 +
1
⋅ ∆I2
3
Output Capacitor Selection
Basically there are two major factors to consider in selecting the type and quantity of the output capacitors.
The first one is the required ESR (Equivalent Series Resistance) which should be low enough to reduce the voltage deviation from its nominal one during its load changes.
The second one is the required capacitance, which should
be high enough to hold up the output voltage. Before the
SC4603 regulates the inductor current to a new value
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
during a load transient, the output capacitor delivers all
the additional current needed by the load. The ESR and
ESL of the output capacitor, the loop parasitic inductance
between the output capacitor and the load combined
with inductor ripple current are all major contributors to
the output voltage ripple. Surface mount speciality polymer aluminum electrolytic chip capacitors in UE series
from Panasonic provide low ESR and reduce the total
capacitance required for a fast transient response.
POSCAP from Sanyo is a solid electrolytic chip capacitor
which has a low ESR and good performance for high frequency with a low profile and high capacitance. Above
mentioned capacitors are recommended to use in
SC4603 applications.
Because the input capacitor is exposed to the large surge
current, attention is needed for the input capacitor. If
tantalum capacitors are used at the input side of the
converter, one needs to ensure that the RMS and surge
ratings are not exceeded. For generic tantalum capacitors, it is wise to derate their voltage ratings at a ratio of
2 to protect these input capacitors.
Input Capacitor Selection
For the top MOSFET, its total power loss includes its conduction loss, switching loss, gate charge loss, output capacitance loss and the loss related to the reverse
recovery of the bottom diode, shown as follows:
Power MOSFET Selection
The SC4603 can drive a P-MOSFET at the high side and
an N-MOSFET synchronous rectifier at the low side. The
use of the high side P-MOSFET eliminates the need for
an external charge pump and simplifies the high side gate
driver circuit.
The input capacitor selection is based on its ripple current level, required capacitance and voltage rating. This
capacitor must be able to provide the ripple current by
the switching actions. For the continuous conduction
mode, the RMS value of the input capacitor can be calculated from:
ICIN(RMS )
PTOP _ TOTAL = I2 TOP _ RMS ⋅ R TOP _ ON +
(Q GD + Q GS 2 ) + Q GT ⋅ VGATE ⋅ fs + (Q OSS + Q rr ) ⋅ VI ⋅ fs
Vout ⋅ ( Vin − Vout )
= IOMAX ⋅
2
Vin
Where:
RG = gate drive resistor,
QGD = the gate to drain charge of the top MOSFET,
QGS2 = the gate to source charge of the top MOSFET,
QGT = the total gate charge of the top MOSFET,
QOSS = the output charge of the top MOSFET, and
Qrr = the reverse recovery charge of the bottom diode.
This current gives the capacitor’s power loss as follows:
PCIN = I2 CIN(RMS ) ⋅ R CIN(ESR )
This capacitor’s RMS loss can be a significant part of the
total loss in the converter and reduce the overall
converter efficiency. The input ripple voltage mainly depends on the input capacitor’s ESR and its capacitance
for a given load, input voltage and output voltage. Assuming that the input current of the converter is constant, the required input capacitance for a given voltage
ripple can be calculated by:
CIN = IOMAX ⋅
For the top MOSFET, it experiences high current and high
voltage overlap during each on/off transition. But for the
bottom MOSFET, its switching voltage is the bottom
diode’s forward drop during its on/off transition. So the
switching loss for the bottom MOSFET is negligible. Its
total power loss can be determined by:
D ⋅ (1 − D)
fs ⋅ ( ∆VI − IOMAX ⋅ R CIN(ESR ) )
PBOT _ TOTAL = I2 BOT _ RMS ⋅ R BOT _ ON + Q GB ⋅ VGATE ⋅ fs + ID _ AVG ⋅ VF
Where:
QGB = the total gate charge of the bottom MOSFET and
VF = the forward voltage drop of the bottom diode.
Where:
D = VO/VI , duty ratio and
∆VI = the given input voltage ripple.
 2008 Semtech Corp.
ITOP _ PEAK ⋅ VI ⋅ fs
⋅
VGATE
RG
10
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
For example, if
For a low voltage and high output current application such
as the 3.3V/1.5V@6A case, the conduction loss is often
dominant and selecting low RDS(ON) MOSFETs will noticeably improve the efficiency of the converter even though
they give higher switching losses.
VCC = 2.25 V,
the reference voltage,
Vref @ 3.3 V
•
100
Internal Reference
VREF @ 2.25 V =
V
The gate charge loss portion of the top/bottom MOSFET’s
total power loss is derived from the SC4603. This gate
charge loss is based on certain operating conditions
(fs, VGATE, and IO).
REF
+
@ 3.3V
Change @ 2.25V • VCC − 3.3V =
500 +
The thermal estimations have to be done for both
MOSFETs to make sure that their junction temperatures
do not exceed their thermal ratings according to their
total power losses PTOTAL, ambient temperature TA and their
thermal resistances R θJA as follows:
500
• 0.1 • 2.25 − 3.3 = 500.5(mV )
100
5
1
2
3
4
FS
ISET
VCC
SYNC
COMP
PDRV
PHASE
NDRV
VSENSE
GND
6
10
7
L1
Vout
9
C9
8
C2
C1
C4
R7
SC4603
R
R8
TJ(max)
R1
P
< TA + TOTAL
R θJA
R9
Loop Compensation Design:
Figure 3. Compensation network provides 3 poles and
2 zeros.
For a DC/DC converter, it is usually required that the
converter has a loop gain of a high cross-over frequency
for fast load response, high DC and low frequency gain
for low steady state error, and enough phase margin for
its operating stability. Often one can not have all these
properties at the same time. The purpose of the loop
compensation is to arrange the poles and zeros of the
compensation network to meet the requirements for a
specific application.
For voltage mode step down applications as shown in
Figure 3, the power stage transfer function is:
1+
G VD (s) = VIN
The SC4603 has an internal error amplifier and requires
the compensation network to connect among the COMP
pin and VSENSE pin, GND, and the output as shown in
Figure 3. The compensation network includes C1, C2,
R1, R7, R8 and C9. R9 is used to program the output
voltage according to:
VOUT = 0.5 ⋅ (1 +
L1
+ s 2L1C 4
R
Where:
R = load resistance and
RC = C4’s ESR.
The compensation network will have the characteristic
as follows:
R7
)
R9
s
s
1+
ω
ωZ1
ωZ 2
⋅
GCOMP (s) = I ⋅
s
s
s
1+
⋅1+
ωP1
ωP 2
1+
As indicated in Internal Reference Change section, the
internal reference voltage (measured at VSENSE pin)
changes slightly if the input voltage of the SC4603 is
away from 3.3V.
 2008 Semtech Corp.
1+ s
s
1
RC ⋅ C4
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
The compensated loop gain will be as given in Figure 4:
Where
ωI =
1
R 7 ⋅ ( C1 + C 2 )
T
ωZ1
Loop gain T(s)
ωo
ωZ2
ωZ1
ωZ 2 =
ωP1
1
=
R1 ⋅ C 2
Gd
0dB
Power stage GVD(s)
ω ESR
C1 + C 2
=
R 1 ⋅ C1 ⋅ C 2
-40dB/dec
1
R 8 ⋅ C9
Figure 4. Asymptotic diagrams of power stage and its
loop gain.
After the compensation, the converter will have the
following loop gain:
Layout Guidelines
T(s) = GPWM ⋅ GCOMP (s) ⋅ GVD (s) =
In order to achieve optimal electrical, thermal and noise
performance for high frequency converters, special attention must be paid to the PCB layouts. The goal of layout optimization is to identify the high di/dt loops and
minimize them. The following guideline should be used to
ensure proper functions of the converters.
s
1
s
s
1
1+
⋅ ωI ⋅ VIN 1 +
VM
RC ⋅ C4
ωZ1
ωZ 2
⋅
⋅
⋅
s
s
L
s
1+
⋅1+
1 + s + s2LC
ωP1
ωP 2
R
1+
Where:
GPWM = PWM gain and
VM = 1.0V, ramp peak to valley voltage of SC4603.
1. A ground plane is recommended to minimize noises
and copper losses, and maximize heat dissipation.
2. Start the PCB layout by placing the power components first. Arrange the power circuit to achieve a
clean power flow route. Put all the connections on
one side of the PCB with wide copper filled areas if
possible.
3. The VCC bypass capacitor should be placed next to
the VCC and GND pins.
4. The trace connecting the feedback resistors to the
output should be short, direct and far away from the
noise sources such as switching node and switching
components.
5. Minimize the traces between PDRV/NDRV and the
gates of the MOSFETs to reduce their impedance to
drive the MOSFETs.
6. Minimize the loop including input capacitors, top/bottom MOSFETs. This loop passes high di/dt current.
Make sure the trace width is wide enough to reduce
copper losses in this loop.
7. ISET and PHASE connections to P-MOSFET for current sensing must use Kelvin connections.
The design guidelines for the SC4603 applications are
as following:
1. Set the loop gain crossover corner frequency
ωC for given switching corner frequency
ωS =2 πfs,
2. Place an integrator at the origin to increase DC
and low frequency gains.
3. Select ωZ1 and ωZ2 such that they are placed
near ωO to damp the peaking and the loop gain
has a -20dB/dec rate to go across the 0dB
line for obtaining a wide bandwidth.
4. Cancel the zero from C4’s ESR by a compensator pole ωP1 (ωP1 = ωESR = 1/( RCC4)),
5. Place a high frequency compensator pole ωp2
(ωp2 = πpfs) to get the maximum attenuation of
the switching ripple and high frequency noise
with the adequate phase lag at ωC.
 2008 Semtech Corp.
ωp1
ω p2
1
(R 7 + R 8 ) ⋅ C 9
ωP 2 =
-20dB/dec
ωc
12
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SC4603
POWER MANAGEMENT
Applications Information - (Cont.)
Layout Guidelines (Cont.)
8. Maximize the trace width of the loop connecting the
inductor, bottom MOSFET and the output capacitors.
9. Connect the ground of the feedback divider and the
compensation components directly to the GND pin
of the SC4603 by using a separate ground trace.
Then connect this pin to the ground of the output
capacitor as close as possible.
Design Example 1: 3.3V to 1.5V @ 5A application with
SC4603 (NH020 footprint).
R15
Vin = 3.3V
1
R3
5
4.7u
1
R2
3.32k
C1
150p
R1
C2
20k
820p
2
3
4
M1
33n
U1
RT 21k
C3
C14
FS
ISET
VCC
PDRV
SY NC/SLEEPPHASE
COMP
NDRV
VSENSE
GND
C10
C11
22u
22u
6
10
7
R6
L1
1.0
M2
8
R5
SC4603
Vo = 1.5V/5A
1.1u
9
1.0
C7
150u
C9
C4
820p
22u
R7
13k
R8
604
R9
6.49k
Figure 5. Schematic for 3.3V/1.5V @ 5A application
 2008 Semtech Corp.
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SC4603
POWER MANAGEMENT
Bill of Materials - 3.3V to 1.5V @ 5A
Item
Qty
Reference
Value
Part No./Manufacturer
1
1
C1
150pF
2
1
C2
820pF
3
1
C3
4.7uF
4
1
C7
150uF
5
1
C9
820pF
6
3
C10,C11,C4
22uF, 1210
7
1
C 14
33nF
8
1
L1
1.1uH
9
1
M1
MOSFET P, S0-8
Fairchild P/N: FDS 6375
10
1
M2
MOSFET N, S0-8
Fairchild P/N: FDS 6680A
11
1
RT
21k
12
1
R1
20k
13
1
R2
3.32k
14
1
R7
13k
15
1
R8
604
16
2
R5,R6
1
17
1
R15
1
18
1
R3
2.94k
19
1
R9
6.49k
20
1
U1
S C 4603
Panasonic. P/N: 6.3V, SP
TDK P/N: C3225X5R0J226M
Semtech P/N: SC4603IMSTRT
Key components:
U1: SC4603, Semtech
M1: FDS 6375, SO-8, Fairchild
M2: FDS 6680A, SO-8, Fairchild
L1: SMT power inductor, 1.1uH ETQP6F1R1H, Panasonic.
Unless specified, all resistors and capacitors are in SMD 0603 package.
Resistors are +/-1% and all capacitors are +/-20%
 2008 Semtech Corp.
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SC4603
POWER MANAGEMENT
PCB Layout - 3.3V to 1.5V @ 6A
Top
Bottom
Top
Bottom
 2008 Semtech Corp.
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SC4603
POWER MANAGEMENT
Outline Drawing - MSOP-10
e
A
DIM
D
A
A1
A2
b
c
D
E1
E
e
L
L1
N
01
aaa
bbb
ccc
N
2X E/2
ccc C
2X N/2 TIPS
E
E1
PIN 1
INDICATOR
12
B
DIMENSIONS
INCHES
MILLIMETERS
MIN NOM MAX MIN NOM MAX
.043
.000
.006
.030
.037
.011
.007
.003
.009
.114 .118 .122
.114 .118 .122
.193 BSC
.020 BSC
.016 .024 .032
(.037)
10
8°
0°
.004
.003
.010
1.10
0.00
0.15
0.75
0.95
0.17
0.27
0.08
0.23
2.90 3.00 3.10
2.90 3.00 3.10
4.90 BSC
0.50 BSC
0.40 0.60 0.80
(.95)
10
0°
8°
0.10
0.08
0.25
D
aaa C
SEATING
PLANE
A2
bxN
bbb
c
GAGE
PLANE
A1
C
H
A
C A-B D
0.25
L
(L1)
DETAIL
SEE DETAIL
SIDE VIEW
01
A
A
NOTES:
1.
CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES).
2. DATUMS -A- AND -B- TO BE DETERMINED AT DATUM PLANE -H3. DIMENSIONS "E1" AND "D" DO NOT INCLUDE MOLD FLASH, PROTRUSIONS
OR GATE BURRS.
4. REFERENCE JEDEC STD MO-187, VARIATION BA.
Land Pattern - MSOP-10
X
DIM
(C)
G
C
G
P
X
Y
Z
Z
Y
P
DIMENSIONS
INCHES
MILLIMETERS
(.161)
.098
.020
.011
.063
.224
(4.10)
2.50
0.50
0.30
1.60
5.70
NOTES:
1.
THIS LAND PATTERN IS FOR REFERENCE PURPOSES ONLY.
CONSULT YOUR MANUFACTURING GROUP TO ENSURE YOUR
COMPANY'S MANUFACTURING GUIDELINES ARE MET.
Contact Information
Semtech Corporation
Power Management Products Division
200 Flynn Road, Camarillo, CA 93012
Phone: (805)498-2111 FAX (805)498-3804
 2008 Semtech Corp.
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