Fairchild FAN6520A Single synchronous buck pwm controller Datasheet

FAN6520A
Single Synchronous Buck PWM Controller
Features
Description
■ Output Range: 0.8V to VIN
The FAN6520A simplifies implementing a complete control and protection scheme for a DC-DC stepdown converter. Designed to drive N-channel MOSFETs in a
synchro-nous buck topology, the FAN6520A integrates
the control, output adjustment, monitoring, and protection functions into a single 8-lead package.
■
■
■
■
■
– 0.8V Internal Reference
– ±1.5% Over Line Voltage and Temperature
Drives N-Channel MOSFETs
Simple Single-Loop Control Design
– Voltage-Mode PWM Control
Fast Transient Response
– High-Bandwidth Error Amplifier
– Full 0% to 100% Duty Cycle
Lossless, Programmable, Over-Current Protection
– Uses Upper MOSFET’s RDS(ON)
Small Converter Size
– 300kHz Fixed-Frequency Oscillator
– Internal Soft-Start
– 8-Lead SOIC
Applications
■ Power Supplies for PC Subsystems and Peripherals
■ MCH, GTL, and AGP Supplies
■ Cable Modems, Set-Top Boxes, and DSL Modems
■ DSP, Memory
■ Low-Voltage Distributed Power Supplies
The FAN6520A employs a single feedback loop and voltage-mode control with fast transient response. The output voltage can be precisely regulated to as low as 0.8V,
with a maximum tolerance of ±1.5% over-temperature
and line-voltage variations. A fixed-frequency oscillator
reduces design complexity, while balancing typical application cost. The error amplifier features a 15MHz gainbandwidth product and an 8V/µs slew rate, which
enables high converter bandwidth for fast transient performance. The resulting PWM duty cycles range from
0% to 100%.
The IC monitors the drop across the upper MOSFET and
inhibits PWM operation appropriately to protect against
over-current conditions. This approach simplifies the
implementation and improves efficiency by eliminating
the need for a current sense resistor.
The FAN6520A is rated for operation from 0° to +70°C,
with the FAN6520AI rated from –40° to +85°C.
Ordering Information
Part Number
Temperature Range
Package
Packing
FAN6520AM
0°C to 70°C
SOIC-8
Rails
FAN6520AMX
0°C to 70°C
SOIC-8
Tape and Reel
FAN6520AIM
–40°C to 85°C
SOIC-8
Rails
FAN6520AIMX
–40°C to 85°C
SOIC-8
Tape and Reel
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
FAN6520A Single Synchronous Buck PWM Controller
October 2006
BOOT
1
HDRV
2
GND
3
LDRV
4
FAN6520A
8
SW
7
COMP/OCSET/SD
6
FB
5
VCC
FAN6520AM 8-Pin SOIC Package
Pin Definitions
Pin #
Name
Description
1
BOOT
Bootstrap Supply Input. Provides a boosted voltage to the high-side MOSFET driver.
Connect to bootstrap capacitor, as shown in Figure 1.
2
HDRV
High-Side Gate-Drive Output. Connect to the gate of the high-side power MOSFET(s).
This pin is monitored by the adaptive shoot-through protection circuitry to determine when
the upper MOSFET has turned off.
3
GND
Ground. The signal and power ground for the IC. Tie this pin to the ground island/plane
through the lowest impedance connection available. Connect directly to source of low-side
MOSFET(s).
4
LDRV
Low-Side Gate-Drive Output. Connect to the gate of the low-side power MOSFET(s).
This pin is monitored by the adaptive shoot-through protection circuitry to determine when
the lower MOSFET has turned off.
5
VCC
VCC. Provides bias power to the IC and the drive voltage for LDRV. Bypass with a ceramic
capacitor as close to this pin as possible.
6
FB
Feedback. This pin is the inverting input of the internal error amplifier. Use this pin, in combination with the COMP/OCSET pin, to compensate the voltage-control feedback loop of
the converter.
7
COMP/
OCSET/SD
Compensation / Over-Current Set Point / Shut Down. This is a multiplexed pin. During
operation, the output of the error amplifier drives this pin. During a short period of time following power-on reset (POR), this pin is used to determine the over-current threshold of the
converter. Pulling COMP/OCSET to a level below 0.8V disables the controller. Disabling the
controller causes the oscillator to stop, the HDRV and LDRV outputs to be held low, and the
soft-start circuitry to restart.
8
SW
Switch Node Input. The SW pin provides return for the high-side bootstrapped driver, is a
sense point for the adaptive shoot-through protection, and is used to monitor the drop
across the upper MOSFET’s RDS(ON) for current limit. Connect as shown in Figure 1.
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
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2
FAN6520A Single Synchronous Buck PWM Controller
Pin Configuration
FAN6520A Single Synchronous Buck PWM Controller
Typical Application
+5V
D BOOT
1
VCC
C HF
Q1
C VCC
2
FAN6520A
8
4
3
COMP/OCSET
C BULK
5
R OCSET
C BOOT
BOOT
7
6
RF
HDRV
LOUT
SW
Q2
+VOUT
C OUT
LDRV
GND
RS
FB
R OFFSET
CF
CI
Figure 1. Typical Application
VCC
POR / SOFT-START
SAMPLE
& HOLD
PWM
COMP/OCSET
20A
FB
BOOT
INHIBIT
OC
ERROR
AMP
0.8V
PWM
GATE
CONTROL
LOGIC
OSC
HDRV
SW
VCC
LDRV
GND
Figure 2. Functional Block Diagram
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
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3
The “Absolute Maximum Ratings” are those values beyond which the safety of the device cannot be guaranteed. The
device should not be operated at these limits. The parametric values defined in the Electrical Characteristics tables
are not guaranteed at the absolute maximum ratings. The “Recommended Operating Conditions” table defines the
conditions for actual device operation.
Parameter
Min.
Max.
Units
VCC to GND
6
V
VBOOT to GND
15
V
HDRV (VBOOT – VSW)
6
V
LDRV
SW to PGND
Continuous
Transient ( t < 50ns, F < 500kHz)
–0.5
6
V
–0.5
6
V
–3
7
V
5.5
V
All other pins
Thermal Information
Symbol
TSTG
TL
Parameter
Min.
Storage Temperature
–65
Typ.
Max.
Units
150
°C
Lead Soldering Temperature, 10 seconds
300
°C
Vapor Phase, 60 seconds
215
°C
Infrared, 15 seconds
220
°C
PD
Power Dissipation, TA = 25°C
ΘJC
Thermal Resistance, Junction-to-Case
40
715
°C/W
mW
ΘJA
Thermal Resistance, Junction-to-Ambient
140
°C/W
Recommended Operating Conditions
Symbol
VCC
Parameter
Conditions
Min.
Typ.
Max.
Units
Supply Voltage
VCC to PGND
4.5
5
5.5
V
TA
Ambient Temperature
TJ
Junction Temperature
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
FAN6520A
0
70
°C
FAN6520AI
–40
85
°C
–40
125
°C
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FAN6520A Single Synchronous Buck PWM Controller
Absolute Maximum Ratings
VCC = 5V and TA = 25°C, using the circuit shown in Figure 1 unless otherwise noted. The • denotes specifications that
apply over the full operating temperature range.
Symbol Parameter
Conditions
Min.
Typ.
Max.
Units
•
1.5
2.4
3.8
mA
•
4.00
4.22
4.45
Supply Current
IVCC
VCC Current
HDRV, LDRV open
Power-On Reset
POR
Rising VCC POR Threshold
VCC POR Threshold Hysteresis
170
V
mV
Oscillator
FOSC
ΔVOSC
Frequency
FAN6520A
•
250
300
340
FAN6520AI
•
230
300
340
Ramp Amplitude
•
1.5
kHz
kHz
Vp-p
Reference
VREF
Reference Voltage
TA = 0 to 70°C
•
788
800
812
mV
FAN6520AI
•
780
800
820
mV
Error Amplifier
GBWP
S/R
DC Gain
88
dB
Gain – Bandwidth Product
15
MHz
Slew Rate
8
V/µs
Gate Drivers
RHUP
HDRV Pulll-Up Resistance
2.5
Ω
RHDN
HDRV Pull-Down Resistance
2.0
Ω
RLUP
LDRV Pull-Up Resistance
2.5
Ω
RLDN
LDRV Pull-Down Resistance
1.0
Ω
Protection/Disable
IOCSET
OCSET Current Source
VDISABLE Disable Threshold
FAN6520A
•
17
FAN6520AI
•
14
20
22
20
24
800
μA
μA
mV
Notes:
1. All limits at operating temperature extremes are guaranteed by design, characterization, and statistical quality
control.
2. AC specifications guaranteed by design/characterization (not production tested).
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
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5
FAN6520A Single Synchronous Buck PWM Controller
Electrical Specifications
Initialization
The FAN6520A automatically initializes upon receipt of
power. The Power-On Reset (POR) function continually
monitors the bias voltage at the VCC pin. When the supply voltage exceeds its POR threshold, the IC initiates
the Over-Current Protection (OCP) sample-and-hold
operation. Upon completion of the OCP sample-and-hold
operation, the POR function initiates soft-start operation.
Over-Current Protection
The over-current function protects the converter from a
shorted output by using the upper MOSFET’s on-resistance, RDS(ON), to monitor the current. This method
enhances the converter’s efficiency and reduces cost by
eliminating the need for a current-sensing resistor. The
over-current function cycles the soft-start function in a
hiccup mode to provide fault protection. A resistor (ROCSET) programs the over-current trip level (see Typical
Application diagram). Immediately following POR, the
FAN6520A initiates the Over-Current Protection sampling-and-hold operation. First, the internal error amplifier is disabled. This allows an internal 20µA current sink
to develop a voltage across ROCSET. The FAN6520A
then samples this voltage at the COMP pin. This sampled voltage, which is referenced to the VCC pin, is held
internally as the over-current set point. When the voltage
across the upper MOSFET, which is also referenced to
the VCC pin, exceeds the over-current set point, the
over-current function initiates a soft-start sequence. Figure 3 shows the inductor current after a fault is introduced while running at 15A. The continuous fault causes
the FAN6520A to go into a hiccup mode with a typical
period of 25ms. The inductor current increases to 18A
during the soft-start interval and causes an over-current
trip. The converter dissipates very little power with this
method. The measured input power for the conditions
shown in Figure 3 is 1.5W.
OUTPUT INDUCTOR
CURRENT
5A/DIV.
The over-current function trips at a peak inductor current
(IPEAK) determined by:
I OCSET × R OCSET
I PEAK = ----------------------------------------------R DS ( ON )
(1)
where IOCSET is the internal OCSET current source
(20µA typical). The OC trip point varies mainly due to the
MOSFET’s RDS(ON) variations. To avoid over-current
tripping in the normal operating load range, find the ROCSET resistor from the equation above with:
• The maximum RDS(ON) at the highest junction
temperature
• The minimum IOCSET from the specification table
ΔI
• Determine IPEAK for I PEAK > I OUT ( MAX ) + ---2
where ΔI is the output inductor ripple current.
For an equation for the ripple current, see “Output Inductor (Lout)” under Component Selection.
Internal circuitry of the FAN6520A does not recognize a
voltage drop across ROCSET larger than 0.5V. Any voltage drop across ROCSET greater than 0.5V sets the overcurrent trip point to:
0.5V
I PEAK = ---------------------(2)
R
DS ( ON )
An over-current trip cycles the soft-start function.
Soft-Start
The POR function initiates the soft-start sequence after
the over-current set point has been sampled. Soft-start
clamps the error amplifier output (COMP pin) and reference input (noninverting terminal of the error amp) to the
internally generated soft-start voltage. Figure 4 shows a
typical start-up interval where the COMP/OCSET pin has
been released from a grounded (system shutdown)
state. Initially, the COMP/OCSET is used to sample the
over-current set point by disabling the error amplifier and
drawing 20µA through ROCSET. Once the over-current
level has been sampled, the soft-start function is initiated. The clamp on the error amplifier (COMP/OCSET
pin) initially controls the converter’s output voltage during
soft-start. The oscillator’s triangular waveform is compared to the ramping error amplifier voltage. This generates SW pulses of increasing width that charge the
output capacitor(s). When the internally generated softstart voltage exceeds the feedback (FB pin) voltage, the
output voltage is in regulation. This method provides a
rapid and controlled output voltage rise. The entire startup sequence typically takes about 11ms.
Figure 3. Over-Current Operation
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
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FAN6520A Single Synchronous Buck PWM Controller
Circuit Description
Q1
HDRV
CIN
L OUT
SW
+VOUT
COUT
LDRV
Figure 5. Printed Circuit Board Power and
Ground Planes or Islands
Figure 4. Soft-Start Interval
The FAN6520A incorporates a MOSFET shoot-through
protection method that allows a converter to both sink
and source current. Care should be exercised when
designing a converter with the FAN6520A when it is
known that the converter may sink current.
When the converter is sinking current, it is behaving as a
boost converter regulating its input voltage. This means
that the converter is boosting current into the VCC rail,
which supplies the bias voltage to the FAN6520A. If this
current has nowhere to go—such as to other distributed
loads on the VCC rail, through a voltage limiting protection device, or other methods—the capacitance on the
VCC bus absorbs the current. This allows the voltage
level of the VCC rail to increase. If the voltage level of the
rail is boosted to a level that exceeds the maximum voltage rating of the FAN6520A, the IC experiences an irreversible failure and the converter is no longer
operational. Ensure that there is a path for the current to
follow, other than the capacitance on the rail, to prevent
this failure mode.
Application Information
LOAD
Q2
Figure 5 shows the critical power components of the converter. To minimize voltage overshoot, the interconnecting wires (indicated by heavy lines) should be part of a
ground or power plane in a printed circuit board. The
components shown in Figure 5 should be located as
close together as possible. Note that the capacitors CIN
and COUT may each represent numerous physical capacitors. Locate the FAN6520A within two inches of the Q1
and Q2 MOSFETs. The circuit traces for the MOSFETs’
gate and source connections from the FAN6520A must
be sized to handle up to 1A peak current.
Figure 5 shows the circuit traces that require additional
layout consideration. Use single point and ground plane
construction for the circuits shown. Minimize any leakage
current paths on the COMP/OCSET pin and locate the
resistor, ROSCET, close to the COMP/OCSET pin
because the internal current source is only 20µA. Provide local VCC decoupling between the VCC and GND
pins. Locate the capacitor, CBOOT, as close as practical
to the BOOT and PHASE pins. All components used for
feedback compensation should be located as close to
the IC as practical.
Vin
Layout Considerations
BOOT
SW
+5V
ROCSET
FAN6520A
Q1
LOUT
CBOOT
DBOOT
+VOUT
COUT
Q2
VCC
LOAD
In any high-frequency switching converter, layout is very
important. Switching current from one power device to
another can generate voltage transients across the
impedances of the interconnecting bond wires and circuit
traces. Use wide, short-printed traces to minimize interconnecting impedances. The critical components should
be located as close together as possible, using ground
plane construction or single-point grounding.
+5V
CVCC
COMP/OCSET
GND
Figure 6. PCB Small Signal Layout Guidelines
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
7
FAN6520A Single Synchronous Buck PWM Controller
Vin
Figure 7 highlights the voltage-mode control loop for a
synchronous-rectified buck converter. The output voltage
(VOUT) is regulated to the reference voltage level. The
error amplifier (Error Amp) output (VE/A) is compared
with the oscillator (OSC) triangular wave to provide a
pulse-width modulated (PWM) wave with an amplitude of
VIN at the SW node. The PWM wave is smoothed by the
output LC filter (LOUT and COUT).
VIN
The compensation network consists of the error amplifier
(internal to the FAN6520A) and the impedance networks
ZIN and ZFB. The goal of the compensation network is to
provide a closed-loop transfer function with the highest
0dB crossing frequency (F0dB) and adequate phase margin. Phase margin is the difference between the closedloop phase at F0dB and 180 degrees. The equations
below relate the compensation network’s poles, zeros,
and gain to the components (R1, R2, R3, C1, C2, and
C3), shown in Figure 7.
OSC
L OUT
Q2
COUT
ESR
SW
PWM
+5V
ZFB
FB
COMP
ERROR
AMP
+VOUT
ZIN
0.8V
C1
COMP
C2
C3
R2
ZIN
R3
VOUT
R1
FB
ERROR
AMP
0.8V
Figure 7. Voltage Mode Buck
Converter Compensation Design
The modulator transfer function is the small-signal transfer function of VOUT/VCOMP. This function is dominated
by a DC gain and the output filter (LOUT and COUT), with
a double-pole break frequency at FLC and a zero at
FESR. The DC gain of the modulator is the input voltage
(VIN) divided by the peak-to-peak oscillator voltage
(ΔVOSC. )
The following equations define the modulator break frequencies as a function of the output LC filter:
1
F LC = ------------------------2π L × C
(3)
1
F ESR = -----------------------------------2π × ESR × C
(4)
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
(5)
1
F P1 = ----------------------------------------C1 C2
2πR 2 ⎛ --------------------⎞
⎝ C 1 + C 2⎠
(6)
1
F Z2 = ---------------------------------------2πC 3 ( R 1 + R 3 )
(7)
1
F P2 = ---------------------2πR 3 C 3
(8)
Use the following steps to locate the poles and zeros of
the compensation network:
DETAILED COMPENSATION
COMPONENTS
ZFB
1
F Z1 = ---------------------2πR 2 C 1
1.
Pick gain (R2/R1) for the desired converter bandwidth.
2.
Place the first zero below the filter’s double pole
(~75% FLC).
3.
Place the second zero at filter’s double pole.
4.
Place the first pole at the ESR zero.
5.
Place the second pole at half the switching frequency.
6.
Check the gain against the error amplifier’s openloop gain.
7.
Estimate phase margin. Repeat if necessary.
Figure 8 shows an asymptotic plot of the DC-DC converter’s gain vs. frequency. The actual modulator gain
has a high gain peak due to the high Q factor of the output filter and is not shown in Figure 8. Using the above
guidelines should give a compensation gain similar to
the curve plotted. The open-loop error amplifier gain
bounds the compensation gain. Check the compensation
gain at FP2 with the capabilities of the error amplifier.
The closed-loop gain is constructed on the graph of Figure 8 by adding the modulator gain (in dB) to the compensation gain (in dB). This is equivalent to multiplying
the modulator transfer function by the compensation
transfer function and plotting the gain.
The compensation gain uses external impedance networks ZFB and ZIN to provide a stable high bandwidth
overall loop. A stable control loop has a gain crossing
with a –20dB/decade slope and a phase margin greater
than 45°. Include worst-case component variations when
determining phase margin.
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FAN6520A Single Synchronous Buck PWM Controller
Feedback Compensation
FZ1 FZ2
FP1
FP2
80
OPEN LOOP
ERROR AMP GAIN
GAIN (dB)
60
40
20
20LOG
(R2/R1)
0
20LOG
(VIN/DVOSC)
MODULATOR
GAIN
-20
COMPENSATION
GAIN
CLOSED LOOP
GAIN
-40
FLC
FESR
-60
10
100
1K
10K
100K
1M
10M
FREQUENCY (Hz)
Figure 8. Asymptotic Bode Plot of Converter Gain
An output capacitor is required to filter the output and
supply the load transient current. The filtering requirements are a function of the switching frequency and the
ripple current. The load transient requirements are a
function of the slew rate (di/dt) and the magnitude of the
transient load current. These requirements are generally
met with a mix of capacitors and careful layout.
Component Selection
Output Capacitors (COUT)
Modern components and loads are capable of producing
transient load rates above 1A/ns. High-frequency capacitors initially supply the transient and slow the current
load rate seen by the bulk capacitors. Effective Series
Resistance (ESR) and voltage rating are typically the
prime considerations for the bulk filter capacitors, rather
than actual capacitance requirements. High-frequency
decoupling capacitors should be placed as close to the
power pins of the load as physically possible. Be careful
not to add inductance in the circuit board wiring that
could cancel the performance of these low-inductance
components. Consult with the load manufacturer on specific decoupling requirements. Use only specialized lowESR capacitors intended for switching-regulator applications for the bulk capacitors. The bulk capacitor’s ESR
determines the output ripple voltage and the initial voltage drop after a high slew-rate transient. An aluminum
electrolytic capacitor’s ESR value is related to the case
size with lower ESR available in larger case sizes; however, the Equivalent Series Inductance (ESL) of these
capacitors increases with case size and can reduce the
usefulness of the capacitor to high slew-rate transient
loading. Since ESL is not a specified parameter, work
with the capacitor supplier and measure the capacitor’s
impedance with frequency to select a suitable component. Generally, multiple small-case electrolytic capacitors perform better than a single large-case capacitor.
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
The output inductor is selected to meet the output voltage ripple requirements and minimize the converter’s
response time to the load transient. The inductor value
determines the converter’s ripple current and the ripple
voltage is a function of the ripple current. The ripple voltage (ΔV) and current (ΔI) are approximated by the following equations:
⎛ V IN – V OUT⎞ V OUT
ΔI = ⎜ ------------------------------⎟ × -------------V IN
⎝ F SW × L ⎠
ΔV ≈ ESR × ΔI
(9)
Increasing the inductance value reduces the ripple current and voltage, but also reduces the converter’s ability
to quickly respond to a load transient. One of the parameters limiting the converter’s response to a load transient
is the time required to change the inductor current.
Given a sufficiently fast control-loop design, the
FAN6520A provides either 0% or 100% duty cycle in
response to a load transient. The response time is the
time required to slew the inductor current from an initial
current value to the transient current level. During this
interval, the difference between the inductor current and
the transient current level must be supplied by the output
capacitor. Minimizing the response time can minimize
the output capacitance required.
Depending on whether there is a load application or a
load removal, the response time to a load transient
(ISTEP) is different. The following equations give the
approximate response time interval for application and
removal of a transient load:
L × I STEP
T RISE = ----------------------------V IN – V OUT
(10)
L × I STEP
T FALL = -----------------------V OUT
(11)
where TRISE is the response time to the application of a
positive ISTEP and TFALL is the response time to a load
removal (negative ISTEP). The worst-case response time
can be either at application or removal of load. Check
both of these equations at the minimum and maximum
output levels for the worst-case response time.
Input Capacitor Selection
Use a mix of input bypass capacitors to control the voltage overshoot across the MOSFETs. Use small ceramic
capacitors for high-frequency decoupling and bulk
capacitors to supply the current needed each time Q1
turns on. Place the small ceramic capacitors physically
close to the MOSFETs and between the drain of Q1 and
the source of Q2. The important parameters for the bulk
input capacitor are the voltage rating and the RMS current rating. For reliable operation, select the bulk capacitor with voltage and current ratings above the maximum
input voltage and the largest RMS current required by
the circuit. The capacitor voltage rating should be at least
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FAN6520A Single Synchronous Buck PWM Controller
Output Inductor (LOUT)
100
The RMS current rating requirement (IRMS) for the input
capacitor of a buck regulator is:
As described in the equations above, the total power
consumed in driving the gate is divided in proportion to
the resistances in series with the MOSFET's internal
gate node, as shown in Figure 9.
BOOT
2
I RMS = I L ( D – D )
(12)
Q1
V OUT
where the converter duty cycle is D = -------------V IN .
For a through-hole design, several electrolytic capacitors
may be needed. For surface-mount designs, solid tantalum capacitors can be used, but caution must be exercised with regard to the capacitor’s surge current rating.
The capacitors must be capable of handling the surge
current at power-up. Some capacitor series available
from reputable manufacturers are surge current tested.
Bootstrap Circuit
The bootstrap circuit uses a charge storage capacitor
(CBOOT) and the internal diode, as shown in Figure 1.
Select these components after the high-side MOSFET
has been chosen. The required capacitance is determined using the following equation:
QG
C BOOT = -------------------------(13)
ΔV BOOT
where QG is the total gate charge of the high-side MOSFET and ΔVBOOT is the voltage droop allowed on the
high-side MOSFET drive. To prevent loss of gate drive,
the bootstrap capacitance should be at least 50 times
greater than the CISS of Q1.
Thermal Considerations
Total device dissipation:
PD = PQ + PHDRV + PLDRV
(14)
where PQ represents quiescent power dissipation.
PQ = VCC × [4mA + 0.036 (FSW – 100)]
(16)
where PH(R) and PH(F) are internal dissipations for the
rising and falling edges respectively.
R HUP
P H ( R ) = P Q1 × -------------------------------------------R HUP + R E + R G
(17)
R HDN
P H ( F ) = P Q1 × -------------------------------------------R HDN + R E + R G
(18)
where:
(19)
where QG1 is total gate charge of Q1 for its applied VGS.
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
RE
RG
G
RHDN
S
SW
Figure 9. Driver Dissipation Model
RG is the polysilicon gate resistance internal to the FET.
RE is the external gate drive resistor implemented in
many designs. Note that the introduction of RE can
reduce driver power dissipation, but excess RE may
cause errors in the “adaptive gate drive” circuitry. For
more information, please refer to Application Note AN6003, “Shoot-through” in Synchronous Buck Converters
at http://www.fairchildsemi.com/an/AN/AN-6006.pdf.
PLDRV is dissipation of the lower FET driver.
PLDRV = PL(R) × PL(F)
(20)
where PH(R) and PH(F) are internal dissipations for the
rising and falling edges, respectively:
R LUP
P L ( R ) = P Q2 × ------------------------------------------R LUP + R E + R G
(21)
R LDN
P L ( F ) = P Q2 × -------------------------------------------R HDN + R E + R G
(22)
PQ2 = QG2 × VGS(Q2) × FSW.
(23)
Power MOSFET Selection
PHDRV represents internal power dissipation of the upper
FET driver.
PQ1 = QG1 × VGS(Q1) × FSW
HDRV
where:
(15)
where FSW is switching frequency (in kHz).
PHDRV = PH(R) × PH(F)
RHUP
For more information on MOSFET selection for synchronous buck regulators, refer to: AN-6005: Synchronous
Buck MOSFET Loss Calculations at http://www.fairchildsemi.com/an/AN/AN-6005.pdf.
Losses in a MOSFET are the sum of its switching (PSW)
and conduction (PCOND) losses.
In typical applications, the FAN6520A converter's output
voltage is low with respect to its input voltage; therefore
the lower MOSFET (Q2) is conducting the full load current for most of the cycle. Choose a MOSFET for Q2 that
has low RDS(ON) to minimize conduction losses.
In contrast, the high-side MOSFET (Q1) has a much
shorter duty cycle and its conduction loss has less
impact. Q1, however, sees most of the switching losses,
so Q1’s primary selection criteria should be gate charge.
www.fairchildsemi.com
10
FAN6520A Single Synchronous Buck PWM Controller
1.25 times greater than the maximum input voltage. A
voltage rating of 1.5 times is a conservative guideline.
Figure 10 shows a MOSFET’s switching interval, with the
upper graph being the voltage and current on the drainto-source and the lower graph detailing VGS vs. time with
a constant current charging the gate. The x-axis, therefore, is also representative of gate charge (QG). CISS =
CGD + CGS and it controls t1, t2, and t4 timing. CGD
receives the current from the gate driver during t3 (as
VDS is falling). The gate charge (QG) parameters on the
lower graph are either specified or can be derived from
the MOSFET’s datasheet.
QGD
4.5V
V SP
(24)
QG(SW)
VGS
t1
(25)
(26)
The driver’s impedance and CISS determine t2, while t3’s
period is controlled by the driver’s impedance and QGD.
Since most of tS occurs when VGS = VSP, use a constant
current assumption for the driver to simplify the calculation of tS:
(27)
t2
t3
t4
t5
Figure 10. Switching Losses and QG
VIN
5V
CGD
where PUPPER is the upper MOSFET’s total losses, PSW
and PCOND are the switching and conduction losses for a
given MOSFET, RDS(ON) is at the maximum junction temperature (TJ), and tS is the switching period (rise or fall
time) and is t2+t3 (Figure 10).
Q G ( SW )
Q G ( SW )
t s ≈ -------------------------- ≈ --------------------------------------------------------------I DRIVER ⎛
V CC – V SP
⎞
⎜ ---------------------------------------------------------⎟
R
+
R
⎝ DRIVER
GATE⎠
QGS
C ISS
ID
V TH
These losses are given by:
⎛ V OUT⎞
2
P COND = ⎜ -----------------⎟ × I OUT × R DS ( ON )
V
⎝ IN ⎠
C GD
VDS
Assuming switching losses are about the same for both
the rising edge and falling edge, Q1’s switching losses
occur during the shaded time when the MOSFET has
voltage across it and current through it.
PUPPER = PSW + PCOND
V DS × I L
P SW = ⎛⎝ ------------------------ × 2 × t s⎞⎠ F SW
2
C ISS
RD
HDRV
G
RGATE
CGS
SW
Figure 11. Drive Equivalent Circuit
Most MOSFET vendors specify QGD and QGS. QG(SW)
can be determined as QG(SW) = QGD + QGS – QTH where
QTH is the gate charge required to reach the MOSFET
threshold (VTH). For the high-side MOSFET, VDS = VIN,
which can be as high as 20V in a typical portable application. Care should be taken to include the delivery of
the MOSFET’s gate power (PGATE) in calculating the
power dissipation required:
PGATE = QG × VCC × FSW
(28)
where QG is the total gate charge to reach VCC.
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
11
FAN6520A Single Synchronous Buck PWM Controller
High-Side Losses
Q2, however, switches on or off with its parallel Shottky
diode conducting, therefore VDS Ý 0.5V. Since PSW is
proportional to VDS, Q2’s switching losses are negligible
and Q2 can be selected based on RDS(ON) only.
Conduction losses for Q2 are given by:
PCOND = (1-D) × IOUT2 × RDS(ON)
(29)
where RDS(ON) is the RDS(ON) of the MOSFET at the
highest operating junction temperature and
V OUT
D = ----------------- is the minimum duty cycle for the converter.
V IN
side MOSFET, the θJ-A, and the maximum allowable
ambient temperature rise:
T J ( MAX ) – T A ( MAX )
P D ( MAX ) = ---------------------------------------------------------θJ – A
(30)
depends primarily on the amount of PCB area that can
be devoted to heat sinking. Refer to Fairchild Application
Note AN-1029 Maximum Power Enhancement Techniques for SO-8 Power MOSFETs at http://www.fairchildsemi.com/an/AN/AN-1029.pdf .
Since DMIN < 20% for portable computers, (1-D) ≈ 1 produces a conservative result, simplifying the calculation.
The maximum power dissipation (PD(MAX) ) is a function
of the maximum allowable die temperature of the low-
©2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
12
FAN6520A Single Synchronous Buck PWM Controller
Low-Side Losses
+5V
D1
1
VCC
2
U1
FAN6520A
R5
8
4
3
7
6
C5a
R2
C5b
HDRV
L OUT
SW
Q2
+VOUT
C9-10
C11
LDRV
R6
GND
R1
FB
C3
SW1
C12
C13
C6
Q1
5
C4
COMP/OCSET
BOOT
R7
R3
C7
C2
R4
C1
Figure 12. 5V to 1.5V 15A DC-DC Converter
Evaluation Board Bill of Materials (1.5V, 15 Amps):
Ref Des
Description
Manufacturer
P/N
Qty
C1
100pF Capacitor, 603
Any
1
C2
0.01µF Capacitor, 603
Any
1
C3
Not Populated
C4
0.1µF Capacitor, 603
Any
0
1
C5A,C5B
1µF Capacitor, 805
Any
3
C6,C11
0.1µF Capacitor, 603
Any
2
C7
Not Populated Capacitor, 603
Any
C9-10,C12,C13
1500µF Capacitor, 6.3V
United
Chemi-con
KZJ6.3VB152M10X12LL
4
0
D1
Diode, 30mA, 30V
Fairchild
MMSD4148
1
L1
1.2µH Inductor
InterTechnical
SC5015-1R2M
1
Q1,Q2
MOSFET
Fairchild
FDD6606
2
R1
2.2kΩ 1% Resistor, 603
Any
1
R2
30.1kΩ 1% Resistor, 603
Any
1
R3
Not Populated
R4
2.49kΩ Resistor, 603
Any
0
1
R5
11.8kΩ Resistor, 603
Any
1
R6
Not Populated Resistor, 603
Any
0
R7
0Ω Resistor, 603
Any
PB1
Pushbutton, miniature
Digikey
P8007S-ND
1
U1
Single Synchronous Buck PWM
Fairchild
FAN6520A
1
TP1,2,3,4
Test Points
KeyStone
1514-2
4
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
1
www.fairchildsemi.com
13
FAN6520A Single Synchronous Buck PWM Controller
Typical Application Circuit
FAN6520A Single Synchronous Buck PWM Controller
Dimensional Outline Drawing
Figure 13. 8-Lead SOIC Package Drawing
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
14
FAN6520A Single Synchronous Buck PWM Controller
© 2005 Fairchild Semiconductor Corporation
FAN6520A Rev. 1.0.5
www.fairchildsemi.com
15
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