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Simple PWM Boost Converter with I/O Disconnect Solves
Malfunctions Caused when VOUT<VIN
By Chin Chang, Director of Application Engineering, Power Management
Semtech Corporation
Introduction
Boost power converters have been widely used for Power Factor Correction (PFC) in AC-DC conversions
[1] and for power management in battery powered DC-DC conversions [2]. Moving beyond low-power
applications, such as cellular phones, smart phones and other portable electronic products, boost
converters are being used more and more in medium-power applications. For example, in computing and
consumer electronics, boost converter-based LED drivers for notebook displays, LCD TVs and monitors
have been developed [3], [4]. In communications and industrial products, simple boost converters are
used in satellite dish auxiliary power supplies and peripheral card supplies [5].
A typical pulse-width-modulation (PWM) boost converter along with a simple controller is shown in Figure
1. This diagram illustrates that there is a DC path from input VIN to output VOUT via the inductor L1 and the
output rectify diode D1. Such topological properties define the normal operation range of the boost
converter at VOUT≥VIN all the time. In the aforementioned applications, this property is fully utilized to
achieve targeted high-efficiency power conversion.
Figure 1: A typical boost converter with a simple controller
Page 2
However, in practical design and operation of the boost converter, designers can face the challenge of
VOUT<VIN under certain conditions and its catastrophic or unwanted consequences. For example,
a) During the boost circuit start up with an uncharged output capacitor C2, huge inrush current results
when the VIN charges the output capacitor from 0V to VIN. After this, the output VOUT is boosted to a
level greater than or equal to VIN, as normal boost converter start up and operation. One traditional
way of limiting the inrush current is to add a current limit resistor in the power path. The issues with
this approach are the added power losses during normal operation and the lower circuit efficiency. In
some high-power applications, with the expense of added circuitry, the current limit resistor is
shortened out after start up.
b) At normal operation, when the circuit output is shortened to ground, there is a direct path to short
the input voltage. This could damage the circuit components and cause catastrophic failure of the
circuit. In some applications, a fuse (resettable or non-resettable) is added in the power path, even
though it is not always accurate.
c) Due to the direct DC path from input to output, once VIN is present, VOUT is moved to VIN level, even
though the boost operation is not initiated and the load is not ready.
In some applications, the presence of unwanted VOUT before system start up sequence could cause
system latch off or malfunction. To address this issue, a power switch (normally a low-frequency type)
needs to be inserted in the input to output path.
Adding an input and output disconnection function in a boost converter easily solves the issues created
when VOUT<VIN. A simple voltage mode PWM controller with the input disconnect function is shown in
Figure 2. It provides a single-chip solution to address the problems that arise when VOUT<VIN. The
necessary control and protection functions it provides allow high-performance power supply design using
a boost converter.
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com
Page 3
Vin
Rs
L1
Q1
C1
D1
Vo
C3
C2
DRV
VIN
OSCILLATOR
VIN
Q
S
PWM
CS
VIN
Q2
GATE
R
CHARG
PUMP
Gm
CA
R1
FB
EA
SS/VREF
R
IS1
OCP/EN
C4
IS2
R2
IS3
SS/HICCUP
CONTROL
C5
GND
SC2604
Figure 2: Boost converter with input/output disconnect based on a simple controller
In Figure 2, three new components are added between the input capacitor C1 and the inductor L1 of the
traditional boost converter. Q1 is a disconnect switch, normally a low-frequency MOSFET. RS is a sensing
resistor that is used to monitor Q1 (and therefore the input) current. C3 is a small ceramic capacitor,
typically 1µF, used to help Q1 turn on and prevent a negative voltage spike when Q1 is disconnected hot
at heavy current.
This simple IC provides a voltage mode PWM control scheme for the boost converter output regulation. It
uses voltage Error Amplifier (EA), oscillator, and PWM comparator blocks. The IC also provides a linear
driver for the disconnect switch and includes current amplifier and charge pump blocks. The charge pump
generates a floating voltage for Q1 drive, which is referred to the input.
Soft Turn-On to Limit Inrush Current
To limit the start-up inrush current that exists in traditional boost converters, it is suggested to slowly turn
on Q1 through linear mode first and then Q2 in switching mode next. The details of the start-up timing are
shown in Figure 3.
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com
Page 4
4.2V
Enable Hiccup
1.25V
VIN
0.625V
VIN+VGS
OCP/EN
1.25V
DRV
0.5V
SS/VREF
GATE
VIN -VD
VO
T2
T1
Note: T1 = C4*0.625V / IS1
T2 = C5*0.75V / IS3
Figure 3: Converter start-up timing diagram
Applying a supply voltage at the VIN pin initiates the IC operation, and the DRV and GATE are held low.
When VIN voltage exceeds UVLO (Under Voltage Lockout) threshold (say 4.2V), an internal current
source IS1 begins to charge the OCP/EN pin capacitor C4. The OCP/EN voltage ramps from 0V to over
1.25V while the voltage between 0.625V to 1.25V provides the linear soft-start range for Q1. This is the
first part of start up that brings the output from 0V to (VIN-VD), where VD is the diode forward drop, with
inrush current control. Adjusting the C4 value can program the converter soft-start time for inrush current
control.
When the OCP/EN voltage is over 1.25V, the OCP (Over Current Protection) hiccup is enabled, and the
SS/VREF pin is released. At this moment, another internal current source IS3 begins to charge the
SS/VREF pin capacitor. When the SS/VREF pin voltage reaches 0.5V, the EA output will rise, then the
PWM comparator begins to switch as EA output reaches 0.4V. The switching regulator output is slowly
ramping up for a soft turn-on. This is the second part of the start-up process that brings the output from
(VIN-VD) to VOUT. The soft-start time can be programmed with a proper capacitor value at SS/VREF pin.
Source-Load Separation During Shutdown
The shutdown of the converter can be achieved by either removing the input supply or pulling the IC
control pin low. As the supply voltage at VIN pin falls below UVLO threshold during a normal operation, the
DRV pin is pulled low to cut off the supply power of the boost converter, while the OCP/EN pin capacitor
is discharged with internal current source IS2. When the OCP/EN pin falls below 1.25V, the SS/VREF pin
is forced to ground and the converter output is completely shutdown. Directly pulling the OCP/EN pin
below 0.52V by an external circuit can also allow a complete shutdown with source-load separation.
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com
Page 5
Hiccup Mode Over-Current Protection
A boost converter with hiccup mode over-current protection will allow system auto-retry and ease of
trouble shooting. In the circuit of Figure 2, when an increasing load causes a voltage of 72mV (Over
Current Threshold setting with Current Sense Resistor) to occur from VIN to CS, a current limit hiccup
sequence is started. The sequence starts by pulling DRV low and discharging the OCP/EN pin with a
current source IS2. When the OCP/EN pin falls below 1.25V, the SS/VREF pin is forced to ground. This is
similar to the UVLO shutdown described in the previous section.
When the voltage on the OCP/EN pin falls to near 0V, the IS2 discharge current becomes IS1 charging
current and the OCP/EN pin starts to charge and DRV is enabled. When the OCP/EN voltage rises from
0.625V to 1.25V, the current in the disconnect switch is allowed to increase from zero up to a maximum
value Imax = 72mV/Rs. If the over-current condition still exists when OCP/EN crosses 1.25V, the hiccup
sequence will restart. If there is no over-current as OCP/EN crosses 1.25V, the SS/VREF pin is released
to rise and allow a soft-start of the switching boost regulator.
Simple Loop Compensation
A voltage-mode PWM control with a constant gain provides a simple control scheme for boost converters
in low-power (Io<2A) applications. With an all-ceramic design and operating at DCM (Discontinuous
Conduction Mode), the small signal characteristic of the converter is a first-order single-pole system. It
can be easily compensated without introducing extra poles or zeroes.
As boost converters run to CCM (Continuous Conduction Mode), a complex pole pair and a Right-HalfPlane (RHP) zero will present in the dynamic characteristic. However, the loop compensation can still be
simple, if the output capacitor ESR is high enough to null the phase lag from the dominant poles, and the
RHP zero is pushed to somewhere way above the crossover frequency. In many medium power (Io~2A5A) applications, all of these conditions could be met by using aluminum electrolytic output capacitors and
properly selecting L1 and C2 values.
A Design Example and Experiment Results
Figure 4 is a typical design for a 12V input and 24V/2A output application operating in CCM.
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com
Page 6
12V INPUT
+ C1
220uF
Q1
IRF7821
RS
L1
1
15m
C1A
4.7uF
C3
1uF
R1
200
Rcc
1R0
D1
2
15uH
A
25V/1.5A OUTPUT
C
C2A
4.7uF
CMSH2-40L
+
C2
220uF/160m
R2
499k
Q2
AO4412
R3
26.1k
U1
C7
C6
1
10nF
2
1uF
3
4
CS
DRV
VIN
OCP/EN
GATE
GND
FB
SS/VREF
SC2604
8
7
6
C8
5
C5
0.33uF
C4
0.1uF
0.33uF
R4
1.43k
Figure 4: A 12V to 24V/2A, 400kHz boost converter
The branches of (Rcc, C7) and (R1, C6) are noise reduction filters for supply voltage at VIN pin and
current sense at CS pin. The system RHP zero is located at 42kHz, but the dominant pole and ESR zero
are located at 1.4kHZ and 4.5kHz, respectively. The loop crossover is designed at 10kHz, which can be
slightly adjusted by the values of (R4, C8). The (R4, C8) branch is equivalent to be connected in parallel
with the bottom resistor of the divider, R3.
Figure 5 shows several typical waveforms when the output is shortened. The inductor current only
presents during retry, which prevents overdraw of the supply power.
25V Output (1V/DIV)
OCP/EN (1V/DIV)
Inductor Current (5A/DIV)
DRV Voltage (5V/DIV)
X=10ms/DIV
Figure 5: Typical waveforms in a boost converter under OCP when controlled by an IC with input
disconnect function.
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com
Page 7
Conclusion
In this article, we described a simple structure improvement of a traditional boost converter and a simple
PWM controller to achieve I/O disconnect, eliminating malfunctions when VOUT<VIN. A boost converter
configured, and a controller controlled with an I/O disconnect function, provides the following benefits:
• Programmable soft turn-on for inrush current control
• Hiccup mode for over-current protection
• Complete shutdown with source-load separation
• Simple loop compensation
• Protection for power MOSFET (Q2) failure
These are important benefits for high-performance power supplies in low- to medium-power applications.
References:
[1] Erickson, R.W. and Maksimovic, D. “Fundamentals of Power Electronics”, 2ed Ed., 2001.
[2]
Semtech Corp., SC120 datasheet, Low Voltage
http://www.semtech.com/images/datasheet/sc120.pdf
Synchronous
Boost
Regulator,
[3] Semtech Corp., SC440A datasheet, High Efficiency Integrated Driver for 6-Strings of 30mA LEDs,
http://www.semtech.com/images/datasheet/sc440a.pdf
[4] Semtech Corp., SC441A datasheet, High Efficiency Integrated Driver for 4-Strings of 150mA LEDs,
http://www.semtech.com/images/datasheet/sc441a.pdf
[5] Semtech Corp., SC2603A datasheet, Simple PWM Boost Converter in Small SOT23-6 Package,
http://www.semtech.com/images/datasheet/sc2603.pdf
[6] Semtech Corp., SC2604 datasheet, Simple PWM Boost Controller with Input Disconnect FET Drive,
http://www.semtech.com/images/datasheet/sc2604.pdf
Semtech Corporation
200 Flynn Road, Camarillo, CA 93012
Phone (805) 498-2111 Fax: (805) 498-3804 Web: www.semtech.com