SEMTECH SC4502EVB

SC4502/SC4502H
1.4Amp, 2MHz Step-Up Switching
Regulator with Soft-Start
POWER MANAGEMENT
Description
Features
‹ Low saturation voltage switch: 210mV
(250mV for the SC4502H)
‹ Constant switching frequency current-mode control
‹ Programmable switching frequency up to 2MHz
‹ Soft-Start function
‹ Input voltage ranges from 1.4V to 16V
‹ Output voltage up to 32V (40V for the SC4502H)
‹ Low shutdown current
‹ Adjustable undervoltage lockout threshold
‹ Small low-profile thermally enhanced lead free
package. This product is fully WEEE and RoHS
compliant.
The SC4502/SC4502H is a high-frequency current-mode
step-up switching regulator with an integrated 1.4A
power transistor. Its high switching frequency (programmable up to 2MHz) allows the use of tiny surface-mount
external passive components. Programmable soft-start
eliminates high inrush current during start-up. The internal switch is rated at 32V (40V for the SC4502H) making the converter suitable for high voltage applications
such as Boost, SEPIC and Flyback.
The operating frequency of the SC4502/SC4502H can
be set with an external resistor. The ability to set the
operating frequency gives the SC4502/SC4502H design
flexibilities. A dedicated COMP pin allows optimization of
the loop response. The SC4502/SC4502H is available
in thermally enhanced 10-pin MLPD package.
Applications
‹
‹
‹
‹
‹
‹
‹
Typical Application Circuit
D1
L1
5V
VOUT
12V
10BQ015
8
OFF ON
C1
2.2µF
3
6,7
IN
SW
SHDN
FB
SS
COMP
GND
C3
47nF
4,5
95
2
SC4502
10
Efficiency
R1
866K
1
ROSC
90
C2
10µF
R3
9
C6
R4
10.5µH, 700KHz
5.3µH, 1.4MHz
85
R2
100K
Efficiency (%)
VIN
Flat screen LCD bias supplies
TFT bias supplies
XDSL power supplies
Medical equipment
Digital video cameras
Portables devices
White LED power supplies
C4
All Capacitors are Ceramic.
80
75
3.3µH, 2MHz
70
65
60
VIN = 5V
VOUT = 12V
55
50
f (MHz)
R3 (KΩ ) R4 (KΩ )
C4 (pF)
C6 (pF)
L1 (µH)
0.7
33.2
23.7
1500
-
10.5 (Falco D08019)
1.4
59.0
9.53
560
-
5.3 (Sumida CDRH5D28)
2
73.2
5.36
330
22
3.3 (Coilcraf t DO1813P)
0.0
0.1
0.2
0.3
0.4
0.5
Load Current (A)
Figure 1(b). Efficiencies of 5V to 12V Boost Converters at
700KHz, 1.4MHz and 2MHz.
Figure 1(a). 5V to 12V Boost Converter.
Revision: July 25, 2005
1
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SC4502/SC4502H
POWER MANAGEMENT
Absolute Maximum Rating
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
Typ
Units
Supply Voltage
VIN
-0.3 to 16
V
SW Voltage
V SW
-0.3 to 32
V
SW Voltage (SC4502H)
V SW
-0.3 to 40
V
FB Voltages
V FB
-0.3 to 2.5
V
VSHDN
-0.3 to VIN + 1
V
Operating Temperature Range
TA
-40 to +85
°C
Thermal Resistance Junction to Ambient (MLPD-10)
θJ A
40
°C/W
Maximum Junction Temperature
TJ
160
°C
Storage Temperature Range
TSTG
-65 to +150
°C
Lead Temperature (Soldering)10 sec
TLEAD
260
°C
ESD Rating (Human Body Model)
ESD
2000
V
SHDN Voltage
Electrical
Electrical Characteristics
Characteristics
Unless other specified: VIN = 2V, SHDN = 1.5V, ROSC = 7.68kΩ, -40°C < TA = TJ < 85°C
Parameter
Test Conditions
Min
Minimum Operating Voltage
Typ
Max
Unit
1.3
1.4
V
16
V
1.260
V
1.267
V
Maximum Operating Voltage
Feedback Voltage
Feedback Voltage Line Regulation
TA = 25°C
1.224
-40°C < TA < 85°C
1.217
1.5V < VIN < 16V
1.242
0.01
%
FB Pin Bias Current
40
80
nA
Error Amplifier Transconductance
60
µΩ−1
Error Amplifier Open-Loop Gain
49
dB
COMP Source Current
VFB = 1.1V
5
µA
COMP Sink Current
VFB = 1.4V
5
µA
VSHDN = 1.5V, VCOMP = 0 ( Not Switching )
1.1
1.6
mA
VSHDN = 0
10
18
µA
1.7
MHz
VIN Quiescent Supply Current
VIN Supply Current in Shutdown
Switching Frequency
1.3
1.5
Maximum Duty Cycle
85
90
Minimum Duty Cycle
%
0
Switch Current Limit
1.4
2
%
A
Switch Saturation Voltage
ISW = 1.3A
210
340
mV
Switch Saturation Voltage (SC4502H)
ISW = 1.3A
250
390
mV
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SC4502/SC4502H
POWER MANAGEMENT
Electrical Characteristics (Cont.)
Unless other specified: VIN = 2V, SHDN = 1.5V, ROSC = 7.68kΩ, -40°C < TA = TJ < 85°C
Parameter
Test C onditions
Swi tch Leakage C urrent
Min
V S W = 5V
Shutdown Threshold Voltage
1.02
Typ
Max
U nit
0.01
1
mA
1.1
1.18
V
µA
VSHDN = 1.2V
-4.6
VSHDN = 0
0
VSS = 0.3V
1.5
µA
Thermal Shutdown Temperature
160
°C
Thermal Shutdown Hysteresi s
10
°C
Shutdown Pi n C urrent
Soft-Start C hargi ng C urrent
Pin Configurations
µA
Ordering Information
TOP VIEW
Device(1)(2)
P ackag e
Temp. Range( TA)
SC4502MLTRT
MLPD-10
-40 to 85°C
SC4502HMLTRT
MLPD-10
-40 to 85°C
S C 4502E V B
Evaluation Board
SC4502HEVB
Evaluation Board
Notes:
(1) Only available in tape and reel packaging. A reel
contains 3000 devices for MLP package.
(2) Lead free product. This product is fully WEEE and
RoHS compliant.
(10 Pin - MLPD, 3 x 3mm)
 2005 Semtech Corp.
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SC4502/SC4502H
POWER MANAGEMENT
Pin Descriptions
Pin
Pin Name
Pin Function
1
COMP
The output of the internal transconductance error amplifier. This pin is used for loop compensation.
2
FB
The inverting input of the error amplifier. Tie to an external resistive divider to set the output voltage.
3
SHDN
Shutdown Pin. The accurate 1.1V shutdown threshold and the 4.6uA shutdown pin current
hysteresis allow the user to set the undervoltage lockout threshold and hysteresis for the switching
regulator. Pulling this pin below 0.1V causes the converter to shut down to low quiescent current.
Tie this pin to IN if the UVLO and the shutdown features are not used. This pin should not be left
floating.
4,5
GND
Ground. Tie both pins to the ground plane. Pins 4 and 5 are not internally connected.
6,7
SW
Collector of the internal power transistor. Connect to the boost inductor and the rectifying diode.
8
IN
9
ROSC
10
SS
Power Supply Pin. Bypassed with capacitors close to the pin.
A resistor from this pin to the ground sets the switching frequency.
Soft-Start Pin. A capacitor from this pin to the ground lengthens the start-up time and reduces startup current.
Exposed Pad
The exposed pad must be soldered to the ground plane on the PCB for good thermal conduction.
Block Diagram
IN
8
SW SW
6
7
4.6µA
SHDN
3
+
-
INTERNAL
SUPPLY
CMP
1.1V
VOLTAGE
REFERENCE
FB
2
1.242V
COMP
1
+
-
REG
ENABL E
THERMAL
SHUTDOWN
CLK
EA
-
R
+
S
PWM
REG
Q
1.5µA
SS
10
+
ILIM
-
I-LIMIT
REG_GOOD
RSENSE
ENABL E
Σ
ROSC
9
CLK
OSCILLATOR
+
+
SLOPE COMP
+
ISEN
4
5
GND GND
Figure 2. SC4502/SC4502H Block Diagram.
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SC4502/SC4502H
POWER MANAGEMENT
Typical Characteristics
Feedback Voltage vs Temperature
Switching Frequency
vs Temperature
ROSC vs Switching Frequency
1.3
1.7
100
1.2
25ºC
10
1.6
VIN = 12V
1.5
VIN = 2V
1.4
1.15
1.3
1
-50
-25
0
25
50
75
100
125
0.0
0.5
1.0
Switch Saturation Voltage
vs Switch Current
500
1.5
2.0
2.5
-50
3.0
25
50
75
125
Switch Saturation Voltage
vs Switch Current
Minimum VIN vs Temperature
1.5
400
85ºC
200
100
1.4
Input Voltage (V)
V CESAT (mV)
300
25ºC
300
85ºC
200
25ºC
100
0
0
1
1.5
2
1.3
1.2
1.1
1
0
0.5
Switch Current (A)
1
1.5
2
-50
-25
Switch Current (A)
1.3
0
25
50
75
100
125
Temperature (ºC)
VIN Current in Shutdown
vs Input Voltage
VIN Quiescent Current vs Temperature
Shutdown Threshold
vs Temperature
50
1.20
Not Switching
VIN = 2V
1.2
VIN = 16V
1.1
1
VIN = 2V
0.9
Shutdown Threshold (V)
40
VIN Current (µA)
VIN Current (mA)
100
SC4502H
400
0.5
0
Temperature (ºC)
500
SC4502
0
-25
Frequency (MHz)
Temperature (ºC)
VCESAT (mV)
Frequency (MHz)
VIN = 2V
1.25
ROSC (KΩ )
Feedback Voltage (V)
ROSC = 7.68KΩ
-40ºC
30
125ºC
20
10
1.15
1.10
1.05
VSHDN = 0
0.8
0
-50
-25
0
25
50
75
Temperature (ºC)
 2005 Semtech Corp.
100
125
1.00
0
5
10
Input Voltage (V)
5
15
20
-50
-25
0
25
50
75
100
125
Temperature (ºC)
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SC4502/SC4502H
POWER MANAGEMENT
Typical Characteristics
VIN Current vs SHDN Pin Voltage
1.2
-3
0.1
VIN = 2V
VIN = 2V
VSHDN = 1.25V
125ºC
0.8
0.6
0.4
125ºC
-40ºC
0.2
25ºC
0.06
0.04
Current (µA)
0.08
VIN Current (mA)
VIN Current (mA)
1
-4
VIN = 2V
-5
VIN = 12V
0.02
-40ºC
0
0
0
0.5
1
1.5
-6
0
0.2
SHDN Voltage (V)
0.4
0.6
0.8
1
1.2
-50
1.4
1.2
1
70
60
50
75
Temperature (ºC)
 2005 Semtech Corp.
100
100
125
125
2.2
2
1.8
40
1.6
30
50
75
2.4
Current Limit (A)
-1
Transconductance (µΩ )
1.6
25
50
VIN = 2V
1.8
0
25
Switch Current Limit
vs Temperature
80
V SS = 0.3V
-25
0
Temperature (ºC)
Transconductance vs Temperature
2
-50
-25
SHDN Voltage (V)
Soft-Start Charging Current
vs Temperature
Current (µA)
Shutdown Pin Current
vs Temperature
VIN Current vs SHDN Pin Voltage
-50
-25
0
25
50
75
Temperature (ºC)
6
100
125
-50
-25
0
25
50
75
100
Temperature (ºC)
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SC4502/SC4502H
POWER MANAGEMENT
Operation
Applications Information
The SC4502/SC4502H is a programmable constantfrequency peak current-mode step-up switching regulator
with an integrated power transistor. As shown in the block
diagram in Figure 2, the power transistor is turned on at
the trailing edge of the clock. Switch current is sensed
with an integrated sense resistor. The sensed current
signal is summed with the slope-compensating ramp
before compared to the output of the error amplifier EA.
The PWM comparator trip point determines the switch
turn-on pulse width. The current-limit comparator ILIM
turns off the power switch when the switch current
exceeds the 2A current-limit threshold. ILIM therefore
provides cycle-by-cycle current limit. Current-limit is not
affected by slope compensation because the current limit
comparator ILIM is not in the PWM signal path.
Setting the Output Voltage
An external resistive divider R1 and R2 with its center tap
tied to the FB pin (Figure 3) sets the output voltage.

 V
R1 = R 2  OUT − 1
1.242V


VOUT
SC4502/SC4502H
R1
40nA
2
FB
R2
Figure 3. The Output Voltage is set with a Resistive Divider
Current-mode switching regulators utiilize a dual-loop
feedback control system. In the SC4502/SC4502H the
amplifier output COMP controls the peak inductor current.
This is the inner current loop. The double reactive poles
of the output LC filter are reduced to a single real pole by
the inner current loop, easing loop compensation. Fast
transient response can be obtained with a simple Type-2
compensation network. In the outer loop, the error amplifier
regulates the output voltage.
The input bias current of the error amplifier will introduce
an error of:
∆VOUT 40nA ⋅ (R1//R 2 )⋅ 100
=
%
VOUT
1.242V
(2)
The percentage error of a VOUT = 5V converter with R1 =
100KΩ and R2 = 301KΩ is
The switching frequency of the SC4502/SC4502H can
be programmed up to 2MHz with an external resistor
from the ROSC pin to the ground. For converters requiring
extremely low or high duty cycles, the operating frequency
can be lowered to maintain the necessary minimum on
time or the minimum off time.
∆VOUT
40nA ⋅ (100 K Ω // 301K Ω ) ⋅ 100
=
= 0.24%
VOUT
1.242V
Operating Frequency and Efficiency
Switching frequency of SC4502/SC4502H is set with
an external resistor from the ROSC pin to the ground. A
graph showing the relationship between R OSC and
switching frequency is given in the “Typical
Characteristics”.
The SC4502/SC4502H requires a minimum input of 1.4V
to operate. A voltage higher than 1.1V at the shutdown
pin enables the internal linear regulator REG in the
SC4502/SC4502H. After VREG becomes valid, the softstart capacitor is charged with a 1.5µA current source. A
PNP transistor clamps the output of the error amplifier
as the soft-start capacitor voltage rises. Since the COMP
voltage controls the peak inductor current, the inductor
current is ramped gradually during soft-start, preventing
high input start-up current. Under fault conditions
(VIN<1.4V or over temperature) or when the shutdown
pin is pulled below 1.1V, the soft-start capacitor is
discharged to ground. Pulling the shutdown pin below 0.1V
reduces the total supply current to 10µA.
 2005 Semtech Corp.
(1)
High frequency operation reduces the size of passive
components but switching losses are higher. The efficiencies
of 5V to 12V converters operating at 700KHz, 1.4MHz
and 2MHz are plotted in Figure 1(b) for SC4502.
Duty Cycle
The duty cycle D of a boost converter in continuous
conduction mode is:
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Applications Information
It is worth noting that IOUTMAX is directly proportional to the
VIN
VOUT + VD
D=
VCESAT
1−
VOUT + VD
1−
(3)
VIN
ratio of V . Equation (4) over-estimates the maximum
OUT
where VCESAT is the switch saturation voltage and VD is the
voltage drop across the rectifying diode.
output current at high frequencies (>1MHz) since
switching losses are neglected in its derivation.
Nevertheless it is a useful first-order approximation.
Using VCESAT = 0.3V, VD = 0.5V and ILIM = 1.4A in (3) and
(4), the maximum output currents for three VIN and VOUT
combinations are shown in Table 1.
Maximum Output Current
In a boost switching regulator the inductor is connected to
the input. The DC inductor current is the input current.
When the power switch is turned on, the inductor current
flows through the switch. When the power switch is off,
the inductor current flows through the rectifying diode to
the output. The maximum output current is the average
diode current. The diode current waveform is trapezoidal
with pulse width (1 – D)T (Figure 4). The output current
available from a boost converter therefore depends on
the converter operating duty cycle. The power switch
current in the SC4502/SC4502H is internally limited to
2A. This is also the maximum inductor or the input current.
By estimating the conduction losses in both the switch
and the rectifying diode, an expression of the maximum
available output current of a boost converter can be
derived as follows:
IOUTMAX =
ILIM VIN 
D VD − D(VD − VCESAT )
−
1 −

VOUT  45
VIN

(4)
Switch Current
(1-D)T
OFF
ON
IOUT
ON
OFF
12
0.820
0.25
3.3
5
0.423
0.80
5
12
0.615
0.53
ON
DMIN
Figure 4. Current Waveforms in a Boost Regulator
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2.5
Example: Determine the maximum operating frequency
of a Li-ion cell to 5V converter using the SC4502.
Assuming that VD=0.5V, VCESAT=0.3V and VIN=2.6V - 4.2V,
the minimum duty ratio can be found using (3).
Diode Current
DT
IOUTMAX ( A )
The operating duty cycle of a boost converter decreases
as VIN approaches VOUT. The PWM modulating ramp in a
current-mode switching regulator is the sensed current
signal. This current ramp is absent unless the switch is
turned on. The intersection of this ramp with the output
of the voltage feedback error amplifier determines the
switch pulse width. The propagation delay time required
to immediately turn off the switch after it is turned on is
the minimum switch on time. Regulator closed-loop
measurement shows that the SC4502/SC4502H has a
minimum on time of about 150ns at room temperature.
The power switch in the SC4502/SC4502H is either not
turned on at all or on for at least 150ns. If the required
switch on time is shorter than the minimum on time, the
regulator will either skip cycles or it will start to jitter.
Inductor Current
ON
D
Considerations for High Frequency Operation
IIN
OFF
VOUT ( V )
Table 1. Calculated Maximum Output Current [ Equation (4)]
where ILIM is the switch current limit.
ON
VIN ( V )
8
4.2
5 + 0.5 = 0.25
=
0.3
1−
5 + 0.5
1−
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Applications Information
operating in continuous-conduction mode is
The absolute maximum operating frequency of the
D⋅ (VIN − VCESAT)
(5)
f ⋅L
where f is the switching frequency and L is the inductance.
DMIN
0.25
=
= 1.67MHz . The
150ns 150ns
actual operating frequency needs to be lower to allow
for modulating headroom.
∆IL =
converter is therefore
Substituting (3) into (5) and neglecting VCESAT ,
The power transistor inside the SC4502/SC4502H is
turned off every switching cycle for an interval determined
by the discharge time of the oscillator ramp plus the
propagation delay of the power switch. This minimum off
time limits the maximum duty cycle of the regulator at a
given switching frequency. A boost converter with high
∆IL =

VIN 
VIN
1 −

f ⋅ L  VOUT + VD 
(6)
In peak current-mode control, the slope of the modulating
(sensed switch current) ramp should be steep enough to
lessen jittery tendency but not so steep that large flux
swing decreases efficiency. Inductor ripple current DIL
between 25%-40% of the peak inductor current limit is a
good compromise. Inductors so chosen are optimized in
size and DCR. Setting ∆IL = 0.3•(1.4A) = 0.42A, VD=0.5V
in (6),
VOUT
VIn ratio requires long switch on time and high duty cycle.
If the required duty cycle is higher than the attainable
maximum, the converter will operate in dropout. (Dropout
is the condition in which the regulator cannot attain its
set output voltage below current limit.)
L=
The minimum off times of closed-loop boost converters set
to various output voltages were measured by lowering their
input voltages until dropout occurs. It was found that the
minimum off time of the SC4502/SC4502H ranged from
80ns to 110ns at room temperature.
VIN
f ⋅ ∆IL


VIN 
VIN 
VIN
 1 −
 =
 1 −
 (7)
VOUT + VD  0.42A ⋅ f 
VOUT + 0.5V 

where L is in µH and f is in MHz.
Equation (6) shows that for a given VOUT, ∆IL is the highest
(VOUT + VD )
Beware of dropout while operating at very low input
voltages (1.5V-2V) with off time approaching 110ns.
Shorten the PCB trace between the power source and
the device input pin, as line drop may be a significant
percentage of the input voltage. A regulator in dropout
may appear as if it is in current limit. The cycle-by-cycle
current limit of the SC4502/SC4502H is duty-cycle and
input voltage invariant and is typically 2A. If the switch
current limit is not at least 1.4A, then the converter is
likely in dropout. The switching frequency should then be
lowered to improve controllability.
when VIN =
Both the minimum on time and the minimum off time
reduce control range of the PWM regulator. Bench
measurement showed that reduced modulating range
started to be a problem at frequencies over 2MHz. Although
the oscillator is capable of running well above 2MHz,
controllability limits the maximum operating frequency.
The input current in a boost converter is the inductor
current, which is continuous with low RMS current ripples.
A 2.2µF-4.7µF ceramic input capacitor is adequate for
most applications.
Inductor Selection
Both ceramic and low ESR tantalum capacitors can be
used as output filtering capacitors. Multi-layer ceramic
capacitors, due to their extremely low ESR (<5mΩ), are
the best choice. Use ceramic capacitors with stable
. If VIN varies over a wide range, then
2
choose L based on the nominal input voltage.
The saturation current of the inductor should be 20%30% higher than the peak current limit (2A). Low-cost
powder iron cores are not suitable for high-frequency
switching power supplies due to their high core losses.
Inductors with ferrite cores should be used.
Input Capacitor
Output Capacitor
The inductor ripple current ∆I L of a boost converter
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SC4502/SC4502H
POWER MANAGEMENT
Applications Information
temperature and voltage characteristics. One may be
tempted to use Z5U and Y5V ceramic capacitors for
output filtering because of their high capacitance and
small sizes. However these types of capacitors have high
temperature and high voltage coefficients. For example,
the capacitance of a Z5U capacitor can drop below 60%
of its room temperature value at –25°C and 90°C. X5R
ceramic capacitors, which have stable temperature and
voltage coefficients, are the preferred type.
The diode current waveform in Figure 4 is discontinuous
with high ripple-content. In a buck converter, the inductor
ripple current ∆IL determines the output ripple voltage.
The output ripple voltage of a boost regulator is however
much higher and is determined by the absolute value of
the inductor current. Decreasing the inductor ripple
current does not appreciably reduce the output ripple
voltage. The current flowing in the output filter capacitor
is the difference between the diode current and the
output current. This capacitor current has a RMS value
of:
IOUT
VOUT
−1
VIN
(8)
If a tantalum capacitor is used, then its ripple current rating
in addition to its ESR will need to be considered.
When the switch is turned on, the output capacitor supplies
the load current IOUT (Figure 4). The output ripple voltage
due to charging and discharging of the output capacitor is
therefore:
∆VOUT =
IOUT ⋅ D ⋅ T
COUT
(9)
For most applications, a 10µF - 22µF ceramic capacitor
is sufficient for output filtering. It is worth noting that the
output ripple voltage due to discharging of a 10µF ceramic
capacitor (9) is higher than that due to its ESR.
Rectifying Diode
For high efficiency, Schottky barrier diodes should be used
as rectifying diodes for the SC4502/SC4502H. These
diodes should have a RMS current rating between 0.5A
and 1A with a reverse blocking voltage of at least a few
 2005 Semtech Corp.
Volts higher than the output voltage. For switching
regulators operating at low duty cycles (i.e. low output
voltage to input voltage conversion ratios), it is beneficial
to use rectifying diodes with somewhat higher RMS
current ratings (thus lower forward voltages). This is
because the diode conduction interval is much longer
than that of the transistor. Converter efficiency will be
improved if the voltage drop across the diode is lower.
The rectifying diodes should be placed close to the SW
pins of the SC4502/SC4502H to minimize ringing due
to trace inductance. Surface-mount equivalents of
1N5817, 1N5819, MBRM120, MBR0520 (ON Semi) and
10BQ015, 10BQ040 (IRF) are all suitable.
Soft-Start
Soft-start prevents a DC-DC converter from drawing
excessive current (equal to the switch current limit) from
the power source during start up. If the soft-start time is
made sufficiently long, then the output will enter regulation
without overshoot. An external capacitor from the SS pin
to the ground and an internal 1.5µA charging current
source set the soft-start time. The soft-start voltage ramp
at the SS pin clamps the error amplifier output. During
regulator start-up, COMP voltage follows the SS voltage.
The converter starts to switch when its COMP voltage
exceeds 0.7V. The peak inductor current is gradually
increased until the converter output comes into regulation.
If the shutdown pin is forced below 1.1V or if a fault
situation is detected, then the soft-start capacitor will
be discharged to ground immediately.
The SS pin can be left open if soft-start is not required.
Shutdown
The input voltage and shutdown pin voltage must be greater
than 1.4V and 1.1V respectively to enable the SC4502/
SC4502H. Forcing the shutdown pin below 1.1V stops
the SC4502/SC4502H from switching. Pulling this pin
below 0.1V completely shuts off the SC4502/SC4502H.
The total VIN shutdown current decreases to 10µA at 2V.
Figure 5 shows several ways of interfacing the control
logic to the shutdown pin. Beware that the shutdown pin
is a high impedance pin. It should always be driven from
a low-impedance source or tied to a resistive divider.
Floating the shutdown pin will result in undefined voltage.
In Figure 5(c) the shutdown pin is driven from a logic
10
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SC4502/SC4502H
POWER MANAGEMENT
Applications Information
IN
IN
SC4502
SC4502H
SC4502
SC4502H
SHDN
SHDN
(a)
VIN
(b)
IN
IN
SC4502
SC4502H
1N4148
SC4502
SC4502H
SHDN
SHDN
(c)
(d)
Figure 5. Methods of Driving the Shutdown Pin
(a) Directly Driven from a Logic Gate
(b) Driven from an Open-drain N-channel MOSFET or an Open-Collector NPN Transistor (VOL < 0.1V)
(c) Driven from a Logic Gate with VOH > VIN
(d) Combining Shutdown with Programmed UVLO (See Section Below).
gate whose VOH is higher than the supply voltage of the
SC4502/SC4502H. The diode clamps the maximum
shutdown pin voltage to one diode voltage above the
input power supply.
Programming Undervoltage Lockout
The SC4502/SC4502H has an internal VIN undervoltage
lockout (UVLO) threshold of 1.4V. The transition from idle
to switching is abrupt but there is no hysteresis. If the
input voltage ramp rate is slow and the input bypass is
limited, then sudden turn on of the power transistor will
cause a dip in the line voltage. Switching will stop if VIN
falls below the internal UVLO threshold. The resulting
output voltage rise may be non-monotonic. The 1.1V
disable threshold of the SC4502/SC4502H can be used
 2005 Semtech Corp.
in conjunction with a resistive voltage divider to raise the
UVLO threshold and to add an UVLO hysteresis. Figure 6
shows the scheme. Both VH and VL (the desired upper
and the lower UVLO threshold voltages) are determined
by the 1.1V threshold crossings, VH and VL are therefore:
 R 
VH = 1 + 3  ⋅ (1.1V )
 R4 
VL = VH − VHYS = VH − IHYSR3
(10)
Re-arranging,
R3 =
R4 =
11
VHYS
IHYS
R3
VH
−1
1.1V
(11)
(12)
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SC4502/SC4502H
POWER MANAGEMENT
Applications Information
VL = VH − VHYS = 2.75V − 0.69V = 2.06V > 1.4V .
IN
Frequency Compensation
6/8
Figure 7 shows the equivalent circuit of a boost converter
using the SC4502/SC4502H. The output filter capacitor
and the load form an output pole at frequency:
I HYS
4.6 µA
R3
SWITCH CLOSED
WHEN Y = “1”
ωp2 =
SHDN
3
(13)
+
where C2 is the output capacitance and ROUT =
Y
-
1.1V
R4
2 ⋅ IOUT
2
=
VOUT ⋅ C2 ROUT ⋅ C2
COMPARATOR
VOUT
is
IOUT
the equivalent load resistance.
SC4502/SC4502H
The zero formed by C2 and its equivalent series resistance
(ESR) is neglected due to low ESR of the ceramic output
capacitor.
Figure 6. Programmable Hysteretic UVLO Circuit
There is also a right half plane (RHP) zero with angular
frequency:
with VL > 1.4 V .
ROUT ⋅ (1 − D)
L
2
Example: Increase the turn on voltage of a VIN = 3.3V boost
converter from 1.4V to 2.75V.
ωZ2 =
ωz2 decreases with increasing duty cycle D and increasing
IOUT. Using the 5V to 12V boost regulator (1.4MHz) in
Figure 1(a) as an example,
Using VH = 2.75V and R4 = 100KΩ in (12),
R3 = 150K Ω .
The resulting UVLO hysteresis is:
R OUT ≥
VHYS = IHYSR3 = 4.6µA • 150K Ω = 0.69V
5V
= 10Ω
0.5A
The turn off voltage is:
I
V
IN
(14)
OUT
POWER
STAGE
VOUT
C5
R1
ESR
R OUT
C2
COMP
Gm
-
FB
+
R3
RO
C6
C4
1.242V
R2
VOLTAGE
REFERENCE
Figure 7. Simplified Block Diagram of a Boost Converter
 2005 Semtech Corp.
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SC4502/SC4502H
POWER MANAGEMENT
Applications Information
ωp1 =
5
12 + 0.5 = 0.62
D=
0.3
1−
12 + 0.5
1−
= 380 rads −1 ⇒ 60Hz
C4 and R3 also forms a zero with angular frequency:
Therefore
ωp2 ≤
ωz1 =
The poles p1, p2 and the RHP zero z2 all increase phase
shift in the loop response. For stable operation, the overall
loop gain should cross 0dB with -20dB/decade slope. Due
to the presence of the RHP zero, the crossover frequency
10Ω ⋅ (1 − 0.62 )
= 272 Krads −1 ⇒ 43.4KHz
5.3µH
2
The spacing between p2 and z2 is the closest when the
converter is delivering the maximum output current from
the lowest V IN . This represents the worst-case
compensation condition. Ignoring C 5 and C 6 for the
moment, C 4 forms a low frequency pole with the
equivalent output resistance RO of the error amplifier:
RO =
1
1
=
R3C4 59KΩ • 560pF
= 30.3 Krads −1 ⇒ 4.8 KHz
2
= 20Krads−1 ⇒ 3.18KHz
(10Ω)⋅ (10µF)
and
ωz2 ≥
1
1
=
ROC4 4.7MΩ • 560pF
Amplifier Open Loop Gain
49dB
=
= 4.7MΩ
Transconductance
60µΩ −1
z2
. Placing z1 near p2 nulls its
3
effect and maximizes loop bandwidth. Thus
should not be higher than
R3C4 ≈
VOUT ⋅ C2
2 ⋅ IOUT(MAX)
(15)
R3 determines the mid-band loop gain of the converter.
Increasing R 3 increases the mid-band gain and the
crossover frequency. However it reduces the phase
margin. The values of R 3 and C 4 can be determined
GND
R3
C3
R4
C4
C6
R2
U1
C1
SHDN
R1
L1
C5
C2
D1
VOUT
VIN
Figure 8. Suggested PCB Layout for the SC4502/SC4502H. Notice that there is no
via directly under the device. All vias are 12mil in diameter.
 2005 Semtech Corp.
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SC4502/SC4502H
POWER MANAGEMENT
Applications Information
empirically by observing the inductor current and the
output voltage during load transient. Compensation is
optimized when the largest R3 and the smallest C4without
producing ringing or excessive overshoot in its inductor
current and output voltage are found. Figures 9(b), 10(c),
11(b) and 11(c) show load transient responses of
empirically optimized DC-DC converters. In a batteryoperated system, compensating for the minimum VIN and
the maximum load step will ensure stable operation over
the entire input voltage range.
C5 adds a feedforward zero to the loop response. In some
cases, it improves the transient speed of the converter.
C6 rolls off the gain at high frequency. This helps to
stabilize the loop. C5 and C6 are often not needed.
Board Layout Considerations
In a step-up switching regulator, the output filter
capacitor, the main power switch and the rectifying diode
carry switched currents with high di/dt. For jitter-free
operation, the size of the loop formed by these
components should be minimized. Since the power switch
is integrated inside the SC4502/SC4502H, grounding
the output filter capacitor next to the SC4502/SC4502H
ground pin minimizes size of the high di/dt current loop.
The input bypass capacitors should also be placed close
to the input pins. Shortening the trace at the SW node
reduces the parasitic trace inductance. This not only
reduces the EMI but also decreases the sizes of the
switching voltage spikes and glitches.
Figure 8 shows how various external components are
placed around the SC4502/SC4502H. The frequencysetting resistor should be placed near the ROSC pin with
a short ground trace on the PC board. These precautions
reduce switching noise pickup at the ROSC pin.
To achieve a junction to ambient thermal resistance (θJA)
of 40°C/W, the exposed pad of the SC4502/SC4502H
should be properly soldered to a large ground plane. Use
only 12mil diameter vias in the ground plane if necessary.
Avoid using larger vias under the device. Molten solder
may seep through large vias during reflow, resulting in
poor adhesion, poor thermal conductivity and low
reliability.
Typical Application Circuits
D1
VIN
L1
3.3V
5.6µH
8
OFF ON
C1
2.2µF
10BQ015
6,7
IN
3
SHDN
10
SW
FB
SC4502
SS
COMP
GND
C3
47nF
4,5
VOUT
12V, 0.3A
R1
174K
2
C2
10µF
1
ROSC
9
R4
9.31K
R3
40.2K
R2
20K
C4
1.8nF
40µs/div
Upper Trace : Output Voltage, AC Coupled, 1V/div
Lower Trace : Inductor Current, 0.5A/div
L1: Sumida CR43
Figure 9(a). 1.35 MHz All Ceramic Capacitor 3.3V to 12V Boost
Converter.
 2005 Semtech Corp.
Figure 9(b). Load Transient Response of the Circuit in Figure
9(a). ILOAD is switched between 0.1A and 0.3A
at 1A/µs.
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SC4502/SC4502H
POWER MANAGEMENT
Typical Application Circuits
Efficiency vs Load Current
95
2.5µH
8
OFF ON 3
1-CELL
LI-ION
C1
2.2µF
10
6,7
IN
SW
SHDN
FB
SC4502
SS
COMP
GND
C3
47nF
10BQ015
4,5
90
5V, 0.5A
85
R1
301K
2
C2
10µF
1
ROSC
9
VOUT
R4
7.68K
R3
34.8K
R2
100K
Efficiency (%)
D1
L1
2.6 - 4.2V
1.5MHz
80
VIN = 4.2V
75
70
65
VIN = 3.6V
VIN = 2.6V
60
VOUT = 5V
55
C4
1nF
50
0.001
0.010
L1: Sumida CDRH5D28
0.100
1.000
Load Current (A)
Figure 10(a). 1.5 MHz All Ceramic Capacitor Single Li-ion Cell
to 5V Boost Converter.
Figure 10(b). Efficiency of the Single Li-ion Cell to 5V Boost
Converter in Figure 10(a).
VIN=2.6V
40µs/div
Upper Trace : Output Voltage, AC Coupled, 0.5V/div
Lower Trace : Inductor Current, 0.5A/div
Figure 10(c). Load Transient Response of the Circuit in Figure .
10(a). ILOAD is switched between 90mA and 0.5A
at 1A/µs.
 2005 Semtech Corp.
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SC4502/SC4502H
POWER MANAGEMENT
Typical Application Circuits
4-CELL
3.6 - 6V
C6
L1
3.3µH
8
OFF ON 3
C1
2.2µF
10
10BQ015
6,7
IN
SW
FB
SC4502
SS
COMP
GND
C3
47nF
2.2µF
SHDN
4,5
R1
60.4K
2
C2
10µF
1
R3
35.7K
ROSC
9
VOUT
5V, 0.5A
D1
R4
7.68K
C4
1.5nF
L2
3.3µH
C6
22pF
R2
20K
L1 and L2: Coiltronics DRQ73-3R3
Figure 11(a). 1.5 MHz All Ceramic Capacitor 4-Cell to 5V SEPIC Converter.
VIN=3.6V
VIN=6V
40µs/div
40µs/div
Upper Trace : Output Voltage, AC Coupled, 0.5V/div
Lower Trace : Input Inductor Current, 0.2A/div
Upper Trace : Output Voltage, AC Coupled, 0.5V/div
Lower Trace : Input Inductor Current, 0.2A/div
Figure 11(b). Load Transient Response of the Circuit in Figure
11(a). I LOAD is switched between 150mA and
450mA at 1A/µs.
 2005 Semtech Corp.
Figure 11(c). Load Transient Response of the Circuit in Figure
11(a). I LOAD is switched between 250mA and
700mA at 1A/µs.
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SC4502/SC4502H
POWER MANAGEMENT
Typical Application Circuits
D2
D3
D4
D5
C5
0.1µF
C6
0.1µF
C7
0.1µF
L1
3.3V
D1
3.3µH
R5
150K
8
3
C1
2.2µF
10
R6
100K
10BQ015
6,7
IN
SW
SHDN
FB
COMP
GND
C3
47nF
4,5
23V (10mA)
C8
1µF
OUT1
8V (0.4A)
R1
274K
2
SC4502
SS
OUT2
C9
0.1µF
1
ROSC
9
R4
7.68K
R3
33.2K
C2
10µF
R2
49.9K
C4
1.5nF
D7
L1 : Coiltronics SD18-3R3
D2 - D7 : BAT54S
D6
OUT3
-8V (10mA)
C10
1µF
Figure 12(a). 1.5MHz Triple-Output TFT Power Supply.
CH4
CH4
CH1
CH1
CH2
CH3
CH2
CH3
2ms/div
CH1 : OUT1 Voltage, 5V/div
CH2 : OUT2 Voltage, 10V/div
CH3 : OUT3 Voltage, 5V/div
CH4 : SHDN Voltage, 2V/div
4ms/div
CH1 : OUT1 Voltage, 5V/div
CH2 : OUT2 Voltage, 10V/div
CH3 : OUT3 Voltage, 5V/div
CH4 : Input Voltage, 2V/div
Figure 12(c). TFT Power Supply Start-up Transient as the
SHDN Pin is stepped from 0 to 2V.
Figure 12(b). TFT Power Supply VIN Start-up Transient.
 2005 Semtech Corp.
17
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SC4502/SC4502H
POWER MANAGEMENT
Typical Application Circuits
D1
14V
8
OFF ON 3 SHDN
C1
2.2µF
10
SC4502H
SS
COMP
GND
C3
47nF
4,5
ROSC
80
2
FB
C2
10µF
1
R3
5.11K
R2
649
75
1.0MHz 10µH
70
65
60
9
R4
1.4MHz 6.8µH
85
R1
17.4K
6,7
SW
90
35V
SS14
IN
Efficiency at 14V input
VOUT
Efficiency (%)
L1
VIN
55
C4
1.5nF
50
0
Figure 13(a). All Ceramic Capacitor High Voltage Application
f (MHz )
R 4(KΩ)
L1
1.0
15.8
10uH IHLP-2525BD _01
1.4
10
6.8uH IHLP-2525BD _01
 2005 Semtech Corp.
0.05
0.1
Load (A)
0.15
0.2
Figure 13(b). Efficiency of the All Ceramic Capacitor High
Voltage Application
18
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SC4502/SC4502H
POWER MANAGEMENT
Outline Drawing - MLPD-10, 3 x 3mm
A
E
B
DIM
A
A1
A2
b
C
D
E
e
L
N
aaa
bbb
E
PIN 1
INDICATOR
(LASER MARK)
A
aaa C
A1
.039
.031
.002
.000
(.008)
.007 .009 .011
.074 .079 .083
.042 .048 .052
.114 .118 .122
.020 BSC
.012 .016 .020
10
.003
.004
0.80
1.00
0.00
0.05
(0.20)
0.18 0.23 0.30
1.87 2.02 2.12
1.06 1.21 1.31
2.90 3.00 3.10
0.50 BSC
0.30 0.40 0.50
10
0.08
0.10
SEATING
PLANE
C
A2
C
1
DIMENSIONS
INCHES
MILLIMETERS
MIN NOM MAX MIN NOM MAX
2
LxN
D
N
bxN
bbb
e
C A B
NOTES:
1. CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES).
2. COPLANARITY APPLIES TO THE EXPOSED PAD AS WELL AS TERMINALS.
Land Pattern - MLPD-10, 3 x 3mm
K
DIM
(C)
H
G
Y
X
Z
C
G
H
K
P
X
Y
Z
DIMENSIONS
INCHES
MILLIMETERS
(.112)
.075
.055
.087
.020
.012
.037
.150
(2.85)
1.90
1.40
2.20
0.50
0.30
0.95
3.80
P
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
 2005 Semtech Corp.
19
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