MPS MP1493

MP1493
3A, 4.2V-16V Input, Fast Transient
Synchronous Step-down Converter
The Future of Analog IC Technology
DESCRIPTION
FEATURES
•
•
•
The MP1493 is a fully integrated, high–
efficiency 3A synchronous rectified step-down
converter. The MP1493 operates at high
efficiency over a wide output current load range.
Adaptive Constant-On-Time (COT) control
mode provides fast transient response, eases
loop stabilization, and operates with a low-cost
electrolytic capacitor.
•
•
•
•
The MP1493 requires a minimum number of
readily available standard external components
and is available in an 8-pin SOIC ROHS
compliant package.
•
•
Wide 4.2V to 16V Operating Input Range
3A Output Current
Adaptive COT for Fast Transient
Response
Low RDS(ON) Internal Power MOSFETs
Proprietary Switching Loss Reduction
Technique
Programmable Switching Frequency
OCP, SCP, OVP, UVP Protection and
Thermal Shutdown
Optional OCP Protection: Latch-off Mode
and Hiccup Mode
Output Adjustable from 0.805V to 13V
APPLICATIONS
•
•
•
Digital Set Top Boxes
Flat Panel Television and Monitors
Distributed Power Systems
All MPS parts are lead-free and adhere to the RoHS directive. For MPS green
status, please visit MPS website under Quality Assurance. “MPS” and “The
Future of Analog IC Technology” are Registered Trademarks of Monolithic
Power Systems, Inc.
TYPICAL APPLICATION
VIN
1
R7
453k
ON/OFF
BST
MP1493
8
499k
IN
5
6
SW
4
3
VOUT 2.5V
FREQ
R1
41k
BYP
FB
EN
7
R2
20k
GND
2
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
ORDERING INFORMATION
Part Number
MP1493DS*
MP1493DS-A
OCP Protection
Latch-off Mode
Hiccup Mode
Package
Top Marking
Free Air Temperature (TA)
SOIC8
MP1493
MP1493-A
-40°C to +85°C
* For Tape & Reel, add suffix –Z (e.g. MP1493DS–Z).
For RoHS Compliant Packaging, add suffix –LF (e.g. MP1493DS–LF–Z)
PACKAGE REFERENCE
SOIC8
ABSOLUTE MAXIMUM RATINGS (1)
Thermal Resistance
Supply Voltage VIN ....................................... 19V
VSW ......................................................................
-0.3V (-5V for <10ns) to 19V (24V for <10ns)
VBST ...................................................... VSW + 6V
All Other Pins ..................................-0.3V to +6V
(2)
Continuous Power Dissipation (TA = +25°C)
SOIC8 ...................................................... 1.39W
Junction Temperature ..............................150°C
Lead Temperature ....................................260°C
Storage Temperature............... -65°C to +150°C
SOIC8..................................... 90 ...... 45... °C/W
Recommended Operating Conditions
(3)
Supply Voltage VIN ...........................4.2V to 16V
Output Voltage VOUT .....................0.805V to 13V
Operating Junction Temp. (TJ). -40°C to +125°C
MP1493 Rev. 1.15
12/9/2013
(4)
θJA
θJC
Notes:
1) Exceeding these ratings may damage the device.
2) The maximum allowable power dissipation is a function of the
maximum junction temperature TJ (MAX), the junction-toambient thermal resistance θJA, and the ambient temperature
TA. The maximum allowable continuous power dissipation at
any ambient temperature is calculated by PD (MAX) = (TJ
(MAX)-TA)/θJA. Exceeding the maximum allowable power
dissipation will cause excessive die temperature, and the
regulator will go into thermal shutdown. Internal thermal
shutdown circuitry protects the device from permanent
damage.
3) The device is not guaranteed to function outside of its
operating conditions.
4) Measured on JESD51-7, 4-layer PCB.
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
ELECTRICAL CHARACTERISTICS
VIN = 12V, TA = +25°C, unless otherwise noted.
Parameters
Supply Current (Shutdown)
Supply Current (Quiescent, Not
Switching)
HS Switch On Resistance
LS Switch On Resistance
Symbol
IIN
IIN
SWLKG
Current Limit (5)
ILIMIT
TON
TOFF
TFB
TOC
VFB
IFB
TSS
VILEN
VIHEN
EN Input Current
IEN
VIN Under Voltage
Threshold Rising
Lockout
VIN Under Voltage
Threshold Hysteresis
Lockout
Min
VEN=2V, VFB=0.9V
HSRDS-ON
LSRDS-ON
Switch Leakage
One-Shot On Time
Minimum Off Time
Fold-back Off Time
OCP hold-off time
Feedback Voltage
Feedback Current
Soft Start Time
EN Rising Threshold
EN Threshold Hysteresis
Condition
VEN=0V
VEN=0V, VSW=0V or
12V
After Soft-Start
Time-out
R7=300kΩ,VOUT=1.2V
4.0
789
VFB=800mV
1.05
Thermal Shutdown
Thermal Shutdown Hysteresis
Units
μA
mA
120
60
mΩ
mΩ
10
μA
5.0
A
250
130
1.25
50
805
10
1
1.35
500
2
0
ns
ns
μs
μs
mV
nA
ms
V
mV
INUVVth
INUVHYS
Max
1
0
ILIM=1
ILIM=1
VEN=2V
VEN=0V
Typ
5
150
821
50
1.6
μA
3.1
V
300
mV
150
25
°C
°C
Note:
5) Guaranteed by design and characterization..
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
PIN FUNCTIONS
SOIC-8
Pin #
Name
1
IN
2
GND
3
SW
4
BST
5
BYP
6
EN
7
FB
8
FREQ
MP1493 Rev. 1.15
12/9/2013
Description
Supply Voltage. The MP1493 operates from a +4.2V to +16V input rail. C1 is needed to
decouple the input rail. Use wide PCB traces and multiple vias to make the connection.
System Ground. This pin is the reference ground of the regulated output voltage. For this
reason care must be taken in PCB layout.
Switch Output. Use wide PCB traces and multiple vias to make the connection.
Bootstrap. A capacitor connected between SW and BST pins is required to form a floating
supply across the high-side switch driver.
Internal LDO output. Decouple with a 1µF ceramic capacitor. X7R or X5R grade dielectric
ceramic capacitors are recommended for their stable temperature characteristics.
EN=1 to enable the MP1493. For automatic start-up, connect EN pin to VIN with a pull-up
resistor.
Feedback. An external resistor divider from the output to GND, tapped to the FB pin, sets
the output voltage.
Switching frequency setting pin during CCM operation. Connect a resistor R7 to IN to set the
switching frequency. An optional 1nF decoupling capacitor can be added to improve any
switching frequency jitter that may be present.
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
TYPICAL PERFORMANCE CHARACTERISTICS
VIN=12V, VOUT=1.2V, L=2.2µH, TA=+25°C, unless otherwise noted.
Line Regulation
100
1.2
1.0
0.8
0.6
0.4
0.2
0.0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
VIN=8V
95
90
VIN=12V
85
80
75
70
65
60
0.01
0.1
1
10
Load Regulation
1.00
0.80
0.60
0.40
VIN=12V
0.20
0.00
IOUT=3A
-0.20
-0.40
-0.60
-0.80
3
IOUT (A)
5
7
9
11
VIN (V)
13
15 16
-1.00
0
0.5
1
1.5
2
2.5
3
IOUT (A)
Frequency vs. Temperature
VOUT VS. IOUT
VOUT=1.2V, Freq=500kHz
30
450
FSW (kHZ)
20
15
10
440
1.22
435
1.2
VOUT(V)
25
430
425
420
415
0
0.5
1
1.5
IOUT (A)
MP1493 Rev. 1.15
12/9/2013
2
2.5
3
400
-40 -20
VIN=16V
1.18
VIN=8V
1.16
VIN=5V
1.12
405
No air flow
VIN=12V
1.14
410
5
0
1.24
445
0 20 40 60 80 100 120140
1.1
0.01
0.1
1
10
IOUT(A)
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=12V, VOUT=1.2V, L=2.2µH, TA=+25°C, unless otherwise noted.
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
TYPICAL PERFORMANCE CHARACTERISTICS (continued)
VIN=12V, VOUT=1.2V, L=2.2µH, TA=+25°C, unless otherwise noted.
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
BLOCK DIAGRAM
Figure 1—Function Block Diagram
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
OPERATION
PWM Operation
The MP1493 is a fully integrated synchronous
rectified step-down switch converter. Adaptive
constant-on-time (COT) control is employed to
provide fast transient response and easy loop
stabilization. At the beginning of each cycle, the
high-side MOSFET (HS-FET) is turned ON when
the feedback voltage (FB) is below the reference
voltage (REF) which indicates insufficient output
voltage. The ON period is determined by the
input voltage and the frequency-set resistor as
follows:
9.3 × RFREQ (kΩ)
(1)
TON (ns) =
+ 40ns
VIN (V) − 0.4
After the ON period elapses, the HS-FET is
turned off. It is turned ON again when FB drops
below REF. By repeating operation in this way,
the converter regulates the output voltage. The
integrated low-side MOSFET (LS-FET) is turned
on when the HS-FET is in its OFF state to
minimize the conduction loss. There will be a
dead short between input and GND if both HSFET and LS-FET are turned on at the same time.
It’s called shoot-through. In order to avoid shootthrough, a dead-time (DT) is internally generated
between HS-FET off and LS-FET on.
When the output current is high, the HS-FET and
LS-FET repeat on/off as described above. In this
operation, the inductor current will never go to
zero. It’s called continuous-conduction-mode
(CCM) operation. In CCM operation, the
switching frequency (Fs) is fairly constant.
Light-Load Operation
When the load current decreases, MP1493
reduces the switching frequency automatically to
maintain high efficiency. As the output current
reduces from heavy-load condition, the inductor
current decreases as well, and eventually comes
close to zero current. The LS-FET driver turns
into tri-state (high Z) whenever the inductor
current reaches zero level. The current modulator
takes over the control of LS-FET and limits the
inductor current to less than -1mA. Hence,
efficiency at light-load condition is optimized.
MP1493 Rev. 1.15
12/9/2013
Figure 2
Floating Driver and Bootstrap Charging
The floating power MOSFET driver is powered by
an external bootstrap capacitor. This floating
driver has its own UVLO protection. This UVLO’s
rising threshold is 2.2V with a hysteresis of
150mV. The bootstrap capacitor voltage is
charged from VCC through N1 (Figure 3). N1
turns on when LS switches turns on and turns off
when LS switch turns off.
Switching Frequency
Adaptive constant-on-time (COT) control is used
in MP1493 and there is no dedicated oscillator in
the IC. The input voltage is feed-forwarded to the
on-time one-shot timer through the resistor R7.
The duty ratio is kept as VOUT/VIN. Hence the
switching frequency is fairly constant over the
input voltage range. The switching frequency
can be set as follows:
FS (kHz) =
106
(2)
9.3 × R7 (kΩ ) VIN (V)
×
+ TDELAY (ns)
VIN (V) − 0.4 VOUT (V)
Where TDELAY is the comparator delay, it’s
about 40ns.
MP1493 is optimized to operate at high switching
frequency but with high efficiency. High switching
frequency makes it possible to utilize small sized
LC filter components to save system PCB space.
Jitter and FB Ramp Slope
Figure 3 and Figure 4 show jitter occurring in
both PWM mode and skip mode. When there is
noise in the VFB downward slope, the ON time of
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
HS-FET deviates from its intended location and
produces jitter. It is necessary to understand that
there is a relationship between a system’s
stability and the steepness of the VFB ripple’s
downward slope. The slope steepness of the VFB
ripple dominates in noise immunity. The
magnitude of the VFB ripple doesn’t directly affect
the noise immunity directly.
To realize the stability when no external ramp is
used, usually the ESR value should be chosen
as follow:
RESR
TSW
T
+ ON
2
≥ 0.7 × π
COUT
(3)
TSW is the switching period.
Ramp with small ESR Cap
When the output capacitors are ceramic ones,
the ESR ripple is not high enough to stabilize the
system, and external ramp compensation is
needed. Skip to application information section
for design steps with small ESR caps.
Figure 3—Jitter in PWM Mode
Figure 6—Simplified Circuit in PWM Mode
with External Ramp Compensation
Figure 4—Jitter in Skip Mode
Ramp with Large ESR Cap
In the case of POSCAP or other types of
capacitor with larger ESR is applied as output
capacitor. The ESR ripple dominates the output
ripple, and the slope on the FB is quite ESR
related. Figure 5 shows an equivalent circuit in
PWM mode with the HS-FET off and without an
external ramp circuit. Turn to application
information section for design steps with large
ESR caps.
In PWM mode, an equivalent circuit with HS-FET
off and the use of an external ramp
compensation circuit (R4, C4) is simplified in
Figure 6. The external ramp is derived from the
inductor ripple current. If one chooses C4, R9,
R1 and R2 to meet the following condition:
⎞
1
1 ⎛ R × R2
< ×⎜ 1
+ R9 ⎟
2π × FSW × C4 5 ⎝ R1 + R 2
⎠
(4)
Where:
IR4 = IC4 + IFB ≈ IC4
(5)
And the ramp on the VFB can then be estimated
as:
VRAMP =
Figure 5—Simplified Circuit in PWM Mode
without External Ramp Compensation
MP1493 Rev. 1.15
12/9/2013
VIN − VOUT
R1 // R2
× TON ×
R 4 × C4
R1 // R2 + R9
(6)
The downward slope of the VFB ripple then
follows
− VOUT
−V
(7)
VSLOPE1 = RAMP =
Toff
R 4 × C4
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
As can be seen from equation 7, if there is
instability in PWM mode, we can reduce either
R4 or C4. If C4 can not be reduced further due to
limitation from equation 4, then we can only
reduce R4. For a stable PWM operation, the
Vslope1 should be design follow equation 8.
TSW
T
+ ON -RESRCOUT
Io × 10-3
0.7
×
π
2
-Vslope1 ≥
VOUT +
2 × L × COUT
TSW -Ton
(8)
Io is the load current.
In skip mode, the downward slope of the VFB
ripple is almost the same whether the external
ramp is used or not. Figure 7 shows the
simplified circuit of the skip mode when both the
HS-FET and LS-FET are off.
Figure 7—Simplified Circuit in skip Mode
The downward slope of the VFB ripple in skip
mode can be determined as follow:
VSLOPE2 =
− VREF
((R1 + R2 ) // Ro) × COUT
(9)
Where Ro is the equivalent load resistor.
As described in Figure 4, VSLOPE2 in the skip mode
is lower than that is in the PWM mode, so it is
reasonable that the jitter in the skip mode is
larger. If one wants a system with less jitter
during ultra light load condition, the values of the
VFB resistors should not be too big, however, that
will decrease the ultra light load efficiency.
Soft Start/Stop
MP1493 employs soft start/stop (SS) mechanism
to ensure smooth output du ring power up and
power shut-down. When the EN pin becomes
high, an internal SS voltage ramps up slowly.
The SS voltage takes over the REF voltage to
the PWM comparator. The output voltage
smoothly ramps up with the SS voltage. Once SS
voltage reaches the same level of the REF
voltage, it keeps ramping up, while REF takes
MP1493 Rev. 1.15
12/9/2013
over the PWM comparator. At this point, the soft
start finishes, it enters steady state operation.
The SS time is about 1ms.
When the EN pin becomes low, the internal SS
voltage is discharged through an internal current
source. Once the SS voltage reaches REF
voltage, it takes over the PWM comparator. The
output voltage will decrease smoothly with SS
voltage until zero level. s
Over-Current Protection (OCP) and ShortCircuit Protection (SCP)
MP1493 has cycle-by cycle over-current limit
control. The inductor current is monitored during
the ON state. And it has two optional OCP/SCP
protection modes: latch-off mode and hiccup
mode.
For MP1493DS, the HS-FET turns off when the
inductor current exceeds the current limit and the
OCP timer—set at 50μs—starts. The OCP
triggers if the inductor current reaches or
exceeds the current limit every cycle in those
50μs. The MP1493DS short-circuit protection
(SCP) occurs when dead shorts occur—when the
inductor current exceeds the current limit and the
FB voltage is lower than 50% of the VREF—and
will trigger the OCP.
For MP1493DS-A, enters hiccup mode, that
periodically restarts the part when the inductor
current peak value exceeds the current limit and
VFB drops below the under-voltage (UV) threshold.
Typically, the UV threshold is 50% below the
REF voltage. In OCP/SCP, MP1493DS-A will
disable the output voltage power, discharge
internal soft-start cap, and then automatically try
to soft-start again. If the over-current circuit
condition still holds after soft-start ends, it
repeats this operation cycle until the over-current
circuit condition disappears, and output rises
back to regulation level.
Over/Under-voltage Protection (OVP/UVP)
MP1493 monitors the output voltage through a
resistor divided feedback (FB) voltage to detect
over and under voltage on the output. When the
FB voltage is higher than 125% of the REF
voltage, it’ll trigger OVP. Once it triggers OVP,
the LS-FET is always on, while the HS-FET is off.
It needs power cycle to power up again. When
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
the FB voltage is below 50% of the REF voltage
(0.805V), UVP will be triggered. Usually UVP
comes with current limit is hit, hence it results in
SCP.
.
UVLO protection
MP1493 has under-voltage lock-out protection
(UVLO). When the input voltage is higher than
the UVLO rising threshold voltage, the MP1493
powers up. It shuts off when the input voltage is
lower than the UVLO falling threshold voltage.
This is non-latch protection.
Thermal Shutdown
Thermal shutdown is employed in MP1493. The
junction temperature of the IC is monitored
internally. If the junction temperature exceeds the
threshold value (typically 150ºC), the converter
shuts off. This is non-latch protection. There is
about 25ºC hysteresis. Once the junction
temperature drops around 125ºC, it initiates a SS
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
APPLICATION INFORMATION
Setting the Output Voltage-Large ESR Caps
For applications that electrolytic capacitor or POS
capacitor with a controlled output of ESR is set
as output capacitors. The output voltage is set by
feedback resistors R1 and R2. As figure 8 shows.
considerable quiescent current loss while too
large R2 makes the FB noise sensitive. It is
recommended to choose a value within 5kΩ50kΩ for R2, using a comparatively larger R2
when Vo is low, etc.,1.05V, and a smaller R2
when Vo is high. And the value of R1 then is
determined as follow:
R2
(11)
R=
1
Figure 8—Simplified Circuit of POS Capacitor
First, choose a value for R2. R2 should be
chosen reasonably, a small R2 will lead to
considerable quiescent current loss while too
large R2 makes the FB noise sensitive. It is
recommended to choose a value within 5kΩ50kΩ for R2, using a comparatively larger R2
when Vo is low, etc.,1.05V, and a smaller R2
when Vo is high. Then R1 is determined as follow
with the output ripple considered:
1
VOUT − ΔVOUT − VREF
2
(10)
R1 =
R2
VREF
ΔVOUT is the output ripple determined by equation
19.
Figure 9—Simplified Circuit of Ceramic
Capacitor
Setting the Output Voltage-Small ESR Caps
When low ESR ceramic capacitor is used in the
output, an external voltage ramp should be
added to FB through resistor R4 and capacitor
C4.The output voltage is influenced by ramp
voltage VRAMP besides R divider. The VRAMP can
be calculated as shown in equation 6, R2 should
be chosen reasonably, a small R2 will lead to
MP1493 Rev. 1.15
12/9/2013
VFB(AVG)
R2
(VOUT -VFB(AVG) ) R4 +R9
The VFB(AVG) is the average value on the FB,
VFB(AVG) varies with the Vin, Vo, and load
condition, etc., its value on the skip mode would
be lower than that of the PWM mode, which
means the load regulation is strictly related to the
VFB(AVG). Also the line regulation is related to the
VFB(AVG) ,if one wants to gets a better load or line
regulation, a lower Vramp is suggested once it
meets equation 8.
For PWM operation, VFB(AVG) value can be
deduced from equation 12.
R1 //R2
1
VFB(AVG) = VREF + VRAMP ×
2
R1 //R2 + R9
(12)
Usually, R9 is set to 0Ω, and it can also be set
following equation 13 for a better noise immunity.
It should also set to be 5 timers smaller than
R1//R2 to minimize its influence on Vramp.
R9 ≤
1
2π× C4 × 2FSW
(13)
Using equation 11 to calculate the output voltage
can be complicated. To simplify the calculation of
R1 in equation 11, a DC-blocking capacitor Cdc
can be added to filter the DC influence from R4
and R9. Figure 10 shows a simplified circuit with
external ramp compensation and a DC-blocking
capacitor. With this capacitor, R1 can easily be
obtained by using equation 14 for PWM mode
operation.
1
(VOUT − VREF − VRAMP )
2
(14)
R1 =
R2
1
VREF + VRAMP
2
Cdc is suggested to be at least 10 times larger
than C4 for better DC blocking performance, and
should also not larger than 0.47uF considering
start up performance. In case one wants to use a
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
larger Cdc for a better FB noise immunity,
combined with reduced R1 and R2 to limit the
Cdc in a reasonable value without affecting the
system start up. Be noted that even when the
Cdc is applied, the load and line regulation are
still Vramp related.
choose the input capacitor that meets the
specification.
The input voltage ripple can be estimated as
follows:
ΔVIN =
IOUT
V
V
× OUT × (1 − OUT )
FS × CIN VIN
VIN
(17)
The worst-case condition occurs at VIN = 2VOUT,
where:
ΔVIN =
Figure 10—Simplified Circuit of Ceramic
Capacitor with DC blocking capacitor
Input Capacitor
The input current to the step-down converter is
discontinuous, therefore a capacitor is required to
supply the AC current to the step-down converter
while maintaining the DC input voltage. Ceramic
capacitors
are
recommended
for
best
performance. In the layout, it’s recommended to
put the input capacitor as close as possible to the
VIN pin.
The capacitance varies significantly over
temperature. Capacitors with X5R and X7R
ceramic dielectrics are recommended because
they are fairly stable over temperature.
The capacitors must also have a ripple current
rating greater than the maximum input ripple
current of the converter. The input ripple current
can be estimated as follows:
ICIN = IOUT ×
VOUT
V
× (1 − OUT )
VIN
VIN
(15)
The worst-case condition occurs at VIN = 2VOUT,
where:
I
(16)
ICIN = OUT
2
For simplification, choose the input capacitor
whose RMS current rating is greater than half of
the maximum load current.
The input capacitance value determines the input
voltage ripple of the converter. If there is an input
voltage ripple requirement in the system design,
MP1493 Rev. 1.15
12/9/2013
I
1
× OUT
4 FS × CIN
(18)
Output Capacitor
The output capacitor is required to maintain the
DC output voltage. Ceramic or POSCAP
capacitors are recommended. The output voltage
ripple can be estimated as:
ΔVOUT =
VOUT
V
1
× (1 − OUT ) × (RESR +
) (19)
FSW × L
VIN
8 × FSW × COUT
In the case of ceramic capacitors, the impedance
at the switching frequency is dominated by the
capacitance. The output voltage ripple is mainly
caused by the capacitance. For simplification, the
output voltage ripple can be estimated by:
ΔVOUT =
VOUT
V
× (1 − OUT )
8 × FS × L × COUT
VIN
2
(20)
The output voltage ripple caused by ESR is very
small. Therefore, an external ramp is needed to
stabilize the system. The external ramp can be
generated through resistor R4 and capacitor C4
following equation 4, 7 and 8.
In the case of POSCAP or electrolytic capacitors,
the ESR dominates the impedance at the
switching frequency. The ramp voltage generated
from the ESR is high enough to stabilize the
system. So the external ramp is not
recommended. A minimum ESR value of 12mΩ
is required to ensure stable operation of the
converter. For simplification, the output ripple can
be approximated to:
ΔVOUT =
VOUT
V
× (1 − OUT ) × RESR
FS × L
VIN
(21)
Maximum output capacitor limitation should be
also considered in design application. MP1493
has an around 1ms soft-start time period. If the
output capacitor value is too high, the output
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
voltage can’t reach the design value during the
soft-start time, and then it will fail to regulate. The
maximum output capacitor value Co_max can be
limited approximately by:
CO _ MAX = (ILIM _ AVG − IOUT ) × Tss / VOUT
(22)
Where, ILIM_AVG is the average start-up current
during soft-start period. Tss is the soft-start time.
Inductor
The inductor is required to supply constant
current to the output load while being driven by
the switched input voltage. A larger value
inductor will result in less ripple current that will
result in lower output ripple voltage. However, the
larger value inductor will have a larger physical
size, higher series resistance, and/or lower
saturation current. A good rule of thumb for
determining the inductance to use is to allow the
peak-to-peak ripple current in the inductor to be
approximately 30~40% of the maximum switch
current limit. Also, make sure that the peak
inductor current is below the maximum switch
current limit. The inductance value can be
calculated by:
L=
VOUT
V
× (1 − OUT )
FS × ΔIL
VIN
(23)
Where ΔIL is the peak-to-peak inductor ripple
current.
Choose an inductor that will not saturate under
the maximum inductor peak current. The peak
inductor current can be calculated by:
ILP = IOUT +
VOUT
V
× (1 − OUT )
2FS × L
VIN
(24)
Application Recommendation
As Figure 8 shows, when output cap is
electrolytic POSCAP, etc with large ESR, no
external ramp is needed. Recommended
parameters are listed below in Table 1 to Table 3
Table 1—300kHz recommended parameters
without External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
13.3
R7
(kΩ)
402
820
1000
Table 2—500kHz recommended parameters
without External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
L
(μH)
3.3
3.3
3.3
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
13.3
R7
(kΩ)
240
510
649
Table 3—700kHz recommended parameters
without External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
L
(μH)
2.2
2.2
2.2
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
13.3
R7
(kΩ)
174
348
475
When output cap is ceramic caps with lower ESR,
external ramp is needed as shown in Fig.9.
Recommended parameters are as listed in Table
4 to Table 6 with R9=0Ω.
Table 4—300kHz recommended parameters
with External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
L
(μH)
3.3
3.3
3.3
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
12.7
R4
(kΩ)
330
698
698
C4
(pF)
220
220
220
R7
(kΩ)
402
820
1000
Table 5—500kHz recommended parameters
with External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
MP1493 Rev. 1.15
12/9/2013
L
(μH)
3.3
3.3
3.3
L
(μH)
3.3
3.3
3.3
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
12.7
R4
(kΩ)
402
549
698
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C4
(pF)
220
220
220
R7
(kΩ)
240
510
649
15
MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
Table 7—Recommended maximum output
capacitor value (FS=500 kHz)
Recommended Conditions: VIN=12V, IOUT=3A
Table 6—700kHz recommended parameters
with External Ramp Compensation
Recommended Conditions: VIN=12V, IOUT=3A
VOUT
(V)
1.2
2.5
3.3
L
(μH)
2.2
2.2
2.2
R1
(kΩ)
12.1
30
40.2
R2
(kΩ)
26.1
14.3
12.7
R4
(kΩ)
330
549
698
C4
(pF)
220
220
220
VOUT
(V)
CO_MAX
(μF)
R7
(kΩ)
174
348
475
BST
IN
1.8
2.5
3.3
5
680
570
390
330
220
The detailed application schematic is shown in
Figure 11, Fig12 and Figure 13. The typical
performance and circuit waveforms have been
shown
in
the
Typical
Performance
Characteristics section.
For more possible
applications of this device, please refer to related
Evaluation Board Data Sheets.
According to equation (22) and some design
abundance
are
reserved,
recommended
maximum output capacitor value is as below
Table 7 shown.
1
1.2
4
MP1493
8
FREQ
5
BYP
6
EN
SW
7
GND
FB
3
2
Figure 11—Typical Application Circuit with No External Ramp
1
BST
IN
4
MP1493
8
FREQ
5
BYP
SW
3
R9
0
FB
EN
7
GND
6
2
Figure 12—Typical Application Circuit with Low ESR Ceramic Capacitor
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
1
BST
IN
4
MP1493
8
FREQ
5
BYP
FB
EN
3
7
Cdc
10nF
GND
6
SW
2
Figure 13—Typtical Application Schematic with Low ESR Ceramic Capacitor
and DC Blocking Capacitor.
Layout Recommendation
1) Put the input capacitors as close as possible
to the IN pin.
2)
Put the decoupling capacitor as close as
possible to the VCC pin.
3)
Put the inductor as close as possible to SW
pin. Make the SW pad as large as possible
to minimize the switching noise interference.
4)
The FB pin is directly connected to the PWM
comparator. It should be routed away from
the noisy SW node.
MP1493 Rev. 1.15
12/9/2013
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MP1493 – 3A, 4.2V-16V INPUT, FAST TRANSIENT SYNCHRONOUS STEP-DOWN CONVERTER
PACKAGE INFORMATION
SOIC8
0.189(4.80)
0.197(5.00)
8
0.050(1.27)
0.024(0.61)
5
0.063(1.60)
0.150(3.80)
0.157(4.00)
PIN 1 ID
1
0.228(5.80)
0.244(6.20)
0.213(5.40)
4
TOP VIEW
RECOMMENDED LAND PATTERN
0.053(1.35)
0.069(1.75)
SEATING PLANE
0.004(0.10)
0.010(0.25)
0.013(0.33)
0.020(0.51)
0.0075(0.19)
0.0098(0.25)
SEE DETAIL "A"
0.050(1.27)
BSC
SIDE VIEW
FRONT VIEW
0.010(0.25)
x 45o
0.020(0.50)
GAUGE PLANE
0.010(0.25) BSC
0o-8o
0.016(0.41)
0.050(1.27)
DETAIL "A"
NOTE:
1) CONTROL DIMENSION IS IN INCHES. DIMENSION IN
BRACKET IS IN MILLIMETERS.
2) PACKAGE LENGTH DOES NOT INCLUDE MOLD FLASH,
PROTRUSIONS OR GATE BURRS.
3) PACKAGE WIDTH DOES NOT INCLUDE INTERLEAD FLASH
OR PROTRUSIONS.
4) LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING)
SHALL BE 0.004" INCHES MAX.
5) DRAWING CONFORMS TO JEDEC MS-012, VARIATION AA.
6) DRAWING IS NOT TO SCALE.
NOTICE: The information in this document is subject to change without notice. Users should warrant and guarantee that third
party Intellectual Property rights are not infringed upon when integrating MPS products into any application. MPS will not
assume any legal responsibility for any said applications.
MP1493 Rev. 1.15
12/9/2013
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18