ANPEC APW7120KE-TUL

APW7120
5V to 12V Supply Voltage, 8-PIN, Synchronous Buck PWM Controller
Features
General Description
•
The APW7120 is a fixed 300kHz frequency, voltage
mode, synchronous PWM controller. The device drives
two low cost N-channel MOSFETs and is designed to
work with single 5~12V or two supply voltage(s),
providing excellent regulation for load transients.
Operating with Single 5~12V Supply Voltage
or two Supply Voltages
•
Drive Dual Low Cost N-Channel MOSFETs
- Adaptive Shoot-Through Protection
•
Built-in Feedback Compensation
The APW7120 integrates controls, monitoring and
protection functions into a single 8-pin package to
provide a low cost and perfect power solution.
- Voltage-Mode PWM Control
- 0~100% Duty Ratio
- Fast Transient Response
•
A power-on-reset (POR) circuit monitors the VCC
supply voltage to prevent wrong logic controls. An
internal 0.8V reference provides low output voltage
down to 0.8V for further applications. An built-in digital
soft-start with fixed soft-start interval prevents the
output voltage from overshoot as well as limiting the
input current. The controller’s over-current protection
monitors the output current by using the voltage drop
across the low-side MOSFET’s RDS(ON), eliminating the
need of a current sensing resistor. Additional under
voltage and over voltage protections monitor the
voltage on FB pin for short-circuit and over-voltage
protections. The over-current protection cycles the
soft-start function until 4 over-current events are
counted.
±2% 0.8V Reference
- Over Line, Load Regulation and
Operating Temp.
•
Programmable Over-Current Protection
- Using RDS(ON) of Low-Side MOSFET
•
•
•
•
Hiccup-Mode Under-Voltage Protection
118% Over-Voltage Protection
Adjustable Output Voltage
Small Converter Size
- 300kHz Constant Switching Frequency
- Small SOP-8 Package
•
•
•
Built-In Digital Soft-Start
Shutdown Control using an External MOSFET
Pulling and holding the voltage on OCSET pin below
0.15V with an open drain device shuts down the
controller.
Lead Free Available (RoHS Compliant)
Applications
•
•
•
Pinouts
Motherboard
Graphics Card
BOOT 1
8 PHASE
UGATE 2
7 OCSET
GND 3
High Current, up to 20A, DC-DC Converters
6 FB
LGATE 4
5 VCC
SOP-8
ANPEC reserves the right to make changes to improve reliability or manufacturability without notice, and advise
customers to obtain the latest version of relevant information to verify before placing orders.
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
1
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APW7120
Ordering and Marking Information
APW7120
Lead Free Code
Handling Code
Temp. Range
Package Code
Package Code
K : SOP-8
Operating Ambient Temp. Range
E : -20 to 70 ° C
Handling Code
TU : Tube
TR : Tape & Reel
Lead Free Code
L : Lead Free Device Blank : Original Device
APW7120
XXXXX
APW7120 K :
XXXXX - Date Code
Note: ANPEC lead-free products contain molding compounds/die attach materials and 100% matte tin plate
termination finish; which are fully compliant with RoHS and compatible with both SnPb and lead-free soldiering
operations. ANPEC lead-free products meet or exceed the lead-free requirements of IPC/JEDEC J STD-020C
for MSL classification at lead-free peak reflow temperature.
Block Diagram
VCC
3VCC
40uA
OCSET
Power On
Reset
Regulator
POR
3VCC
67%VREF
UV
0.4V
OC
2.5V
Enable
0.15V
Soft-Start
and Fault
Logic
BOOT
OV
UGATE
118%VREF
Inhibit
Soft-Start
COMP
FB
VREF
0.8V
PWM
Gm
Amplifier
Rev. A.4 - Jan., 2006
3VCC
LGATE
Oscillator
Copyright  ANPEC Electronics Corp.
PHASE
Gate
Control
FOSC
300kHz
2
GND
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APW7120
Application Circuit
L1
1uH
D1
1N4148
VBIAS
VIN
+5V/12V
C5
1uF
1
C2
0.1uF
+5/12V
C3, C4
820uF x2
BOOT
R4
2.2
UGATE
5
PHASE
VCC
C1
1uF
U 1 OCSET
APW7120
6
Q1
APM2512
2
8
7
VOUT
1.8V/15A
C6, C7
1000uF x2
Q2
APM2512
4
FB
L2
1.5uH
R5
LGATE
GND
3
Shutdown
R1
1.5k
Q3
2N7002
R2
1.2k
C8
0.1uF
R3
200
C3, C4 : 820µF/16V , ESR=25 mΩ
C6, C7 : 1000µF/6.3V, ESR=30 mΩ
Absolute Maximum Ratings
Symbol
VCC
VBOOT
Parameter
Rating
Unit
VCC Supply Voltage (VCC to GND)
-0.3 ~ 16
V
BOOT Voltage (BOOT to PHASE)
-0.3 ~ 16
V
<400nS pulse width
>400nS pulse width
-5 ~ VBOOT+0.3
-0.3 ~ VBOOT+0.3
V
<400nS pulse width
>400nS pulse width
-5 ~ VCC+0.3
-0.3 ~ VCC+0.3
V
<400nS pulse width
>400nS pulse width
-10 ~ 30
-0.3 ~ 16
V
UGATE Voltage (UGATE to PHASE)
LGATE Voltage (LGATE to GND)
PHASE Voltage (PHASE to GND)
VI/O
Input Voltage (OCSET, FB to GND)
Maximum Junction Temperature
TSTG
Storage Temperature
-0.3 ~ 7
V
150
o
-65 ~ 150
o
o
TSDR
Maximum Soldering Temperature, 10 Seconds
300
VESD
Minimum ESD Rating (Human Body Mode) (Note 2)
±2
C
C
C
kV
Note 1: Absolute Maximum Ratings are those values beyond which the life of a device may be impaired.
Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Note 2: The device is ESD sensitive. Handling precautions are recommended.
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
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APW7120
Thermal Characteristics
Symbol
Parameter
θJA
Value
Junction-to-Ambient Resistance in free air (Note 3)
Unit
o
160
C/W
Note 3: θJA is measured with the component mounted on a high effective thermal conductivity test board in free air.
Recommended Operating Conditions
Symbol
Parameter
VCC
VCC Supply Voltage
VOUT
Converter Output Voltage
VIN
Converter Input Voltage
IOUT
Converter Output Current
TA
(Note 4)
Unit
4.5 ~ 13.2
V
0.8 ~ 80%VIN
V
2.2 ~ 13.2
V
0 ~ 20
Ambient Temperature
TJ
Range
Junction Temperature
A
-20 ~ 70
o
-20 ~ 125
o
C
C
Note 4: Please refer to the typical application circuit.
Electrical Characteristics
Unless otherswise specified, these specifications apply over VCC = 12V, VBOOT = 12V and TA = -20 ~ 70oC.
Typlcal values are at TA = 25oC.
Symbol
Parameter
Test Conditions
APW7120
Unit
Min
Typ
Max
-
2.1
6
mA
-
1.5
4
mA
Rising VCC Threshold
3.8
4.1
4.4
V
Hysteresis
0.3
0.45
0.6
V
250
300
350
kHz
-
1.5
-
VP-P
SUPPLY CURRENT
IVCC
VCC Nominal Supply Current
UGATE and LGATE Open
VCC Shutdown Supply Current
POWER-ON RESET
OSCILLATOR
FOSC
∆VOSC
Free Running Frequency
Ramp Amplitude
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
4
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APW7120
Electrical Characteristics (Cont.)
Unless otherswise specified, these specifications apply over VCC = 12V, VBOOT = 12V and TA = -20 ~ 70oC.
Typlcal values are at TA = 25oC.
Symbol
Parameter
Test Conditions
APW7120
Unit
Min
Typ
Max
-
0.8
-
V
REFERENCE VOLTAGE
VREF
Reference Voltage
Measured at FB Pin
Accuracy
TA =-20~70°C
-2.0
-
+2.0
%
Line Regulation
VCC=12 ~ 5V
-
0.05
0.5
%
DC Gain
-
86
-
dB
FP1
First Pole Frequency
-
0.4
-
Hz
FZ
Zero Frequency
-
0.4
-
kHz
FP2
Second Pole Frequency
-
430
-
kHz
Average UGATE Duty Range
0
-
85
%
FB Input Current
-
-
0.1
µA
ERROR AMPLIFIER
PWM CONTROLLER GATE DRIVERS
TD
UGATE Source
VBOOT-PHASE =12V, VUGATE-PHASE =6V
1.0
2.0
-
A
UGATE Sink
VBOOT-PHASE =12V, VUGATE-PHASE=1V
-
3.5
7
Ω
LGATE Source
VCC=12V, VLGATE=6V
1.0
1.9
-
A
LGATE Sink
VCC=12V, VLGATE=1V
-
2.6
5
Ω
Dead-Time
Guaranteed by Design
-
40
100
nS
35
40
45
µA
0.37
0.4
0.43
V
64
67
70
%
-
45
-
mV
115
118
121
%
2
3.8
5
mS
0.1
0.15
0.3
V
-
40
-
mV
PROTECTIONS
IOCSET OCSET Current Source
VPHASE=0V, Normal Operation
Over-Current Reference Voltage TA =-20~70°C
UVFB
FB Under-Voltage Threshold
Rising VFB
FB Under-Voltage Hysteresis
Over-Voltage Threshold
Rising VFB
SOFT-START AND SHUTDOWN
TSS
Soft-Start Interval
OCSET Shutdown Threshold
Falling VOCSET
OCSET Shutdown Hysteresis
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
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APW7120
Functional Pin Description
BOOT (Pin 1)
where R1 is the resistor connected from VOUT to FB ,
and R2 is the resistor connected from FB to GND. The
FB pin is also monitored for under and over-voltage
events.
This pin provides ground referenced bias voltage to
the high-side MOSFET driver. A bootstrap circuit with
a diode connected to 5~12V is used to create a
voltage suitable to drive a logic-level N-channel
MOSFET.
OCSET (Pin 7)
UGATE (Pin 2)
The OCSET is a dual-function input pin for overcurrent protection and shutdown control. Connect a
resistor (ROCSET) from this pin to the Drain of the lowside MOSFET. This resistor, an internal 40µA current
source (I OCSET), and the MOSFET’s on-resistance
(RDSON) set the converter over-current trip level (IPEAK)
according to the following formula:
Connect this pin to the high-side N-channel MOSFET’s
gate. This pin provides gate drive for the high-side
MOSFET.
GND (Pin 3)
The GND terminal provides return path for the IC’s bias
current and the low-side MOSFET driver’s pull-low
current. Connect the pin to the system ground via very
low impedance layout on PCBs.
40µ A ⋅ R OCSET - 0.4V
(A)
R DSON
Pulling and holding this pin below 0.15V with an open
I PEAK =
LGATE (Pin 4)
drain device, with very low parasitic capacitor, shuts
down the IC with floating output and also resets the
over-current counter. Releasing OCSET pin initiates a
new soft-start and the converter works again.
Connect this pin to the low-side N-channel MOSFET’s
gate. This pin provides gate drive for the low-side
MOSFET.
VCC (Pin 5)
PHASE (Pin 8)
Connect this pin to a 5~12V supply voltage. This pin
provides bias supply for the control circuitry and the
low-side MOSFET driver. The voltage at this pin is
monitored for the Power-On Reset (POR) purpose.
The pin provides return path for the high-side MOSFET
driver’s pull-low current. Connect this pin to the highside MOSFET’s source.
FB (Pin 6)
This pin is the inverting input of the internal Gm
amplifier. Connect this pin to the output (VOUT) of the
converter via an external resistor divider for closedloop operation. The output voltage set by the resistor
divider is determined using the following formula :
V OUT = 0.8V ⋅ ( 1 +
R1
)
R2
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
(V)
6
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APW7120
Typical Operating Characteristics
Reference Voltage vs Junction Temperature
Switching Frequency vs Junction Temperature
350
0.812
Switching Frequency, FOSC (kHz)
Reference Voltage, V REF (V)
0.810
0.808
0.806
0.804
0.802
0.800
0.798
0.796
0.794
0.792
0.790
0.788
340
330
320
310
300
290
280
270
260
250
-50
-25
0
25
50
75
100
125
150
-50
-25
Junction Temperature ( C)
OCSET Current vs Junction Temperature
25
50
75
100
125
150
VCC POR Threshold Voltage vs Junction Temperature
45
4.4
VCC POR Threshold Voltage (V)
44
OCSET Current , I OCSET (µA)
0
Junction Temperature (oC)
o
43
42
41
40
39
38
37
36
35
4.3
4.2
4.1
Rising VCC
4.0
3.9
3.8
Falling VCC
3.7
3.6
3.5
3.4
-50
-25
0
25
50
75
100
125
150
-50
Junction Temperature ( C)
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
-25
0
25
50
75
100
125
150
Junction Temperature (oC)
o
7
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APW7120
Typical Operating Characteristics (Cont.)
OCSET Shutdown Threshold Voltage (V)
OCSET Shutdown Threshold Voltage
vs Junction Temperature
0.20
Falling VOCSET
0.18
0.16
0.14
0.12
0.10
-50
-25
0
25
50
75
100
125
150
Junction Temperature (oC)
Operating Waveforms
(Refer to the typical application circuit, VBAIS=VIN=+12V supplied by an ATX Power Supply)
1. Load Transient Response : IOUT = 0A -> 15A -> 0A
- IOUT slew rate = ±15A/µS
IOUT = 0A -> 15A
IOUT = 0A -> 15A -> 0A
IOUT = 15A -> 0A
VOUT=1.8V
VOUT
1
1
VOUT
VOUT
VUGATE
VUGATE
3
3
VUGATE
3
15A
IOUT
2
2
1
IOUT
0A
Ch1 : VOUT, 100mV/Div, DC,
Ch1 : VOUT, 100mV/Div, DC,
Offset = 1.8V
Offset = 1.8V
IOUT
2
Ch1 : VOUT, 100mV/Div, DC,
Offset = 1.8V
Ch2 : IOUT, 10A/Div
Ch2 : IOUT, 10A/Div
Ch2 : IOUT, 10A/Div
Ch3 : VUGATE, 20V/Div, DC
Ch3 : VUGATE, 20V/Div, DC
Ch3 : VUGATE, 20V/Div, DC
Time : 2µS/Div
Time : 50µS/Div
Time : 2µS/Div
BW = 20 MHz
BW = 20 MHz
BW = 20 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
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APW7120
Operating Waveforms (Cont.)
(Refer to the typical application circuit, VBIAS=VIN=+12V supplied by an ATX Power Supply)
2. UGATE and LGATE Switching Waveforms
Falling VUGATE
Rising VUGATE
IOUT = 15A
VLGATE
VUGATE
VLGATE
VUGATE
1,2
1,2
Ch1 : VUGATE, 5V/Div, DC
Ch2 : VLGATE, 2V/Div, DC
Ch1 : VUGATE, 5V/Div, DC Ch2 : VLGATE, 2V/Div, DC
Time : 20nS/Div
BW = 500 MHz
Time : 20nS/Div
BW = 500 MHz
3. Powering ON / OFF
Powering ON
Powering OFF
IOUT = 15A
VCC
VCC
IL
VOUT
1,3
1,3
2
2
IL
VCC
VOUT
IL
VOUT
IOUT = 15A
Ch1 : VCC, 2V/Div, DC
Ch2 : VOUT, 1V/Div, DC
Ch1 : VCC, 2V/Div, DC
Ch2 : VOUT, 1V/Div, DC
Ch3 : IL, 5A/Div, DC
Time : 5mS/Div
Ch3 : IL, 5A/Div, DC
Time : 5mS/Div
BW = 20 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
BW = 20 MHz
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APW7120
Operating Waveforms (Cont.)
(Refer to the typical application circuit, VBIAS=VIN=+12V supplied by an ATX Power Supply)
4. Enabling and Shutting Down
Enabling by Releasing OCSET Pin
3
Shutting Down by Pulling OCSET Low
VOCSET
3
VOCSET
2
VUGATE
2
VUGATE
VOUT
1
VOUT
1
IOUT=2A
Ch1 : VOUT, 1V/Div, DC
Ch2 : VUGATE, 20V/Div, DC
Ch3 : VOCSET, 2V/Div, DC Time : 2mS/Div
Ch1 : VOUT, 1V/Div, DC
Ch2 : VUGATE, 20V/Div, DC
Ch3 : VOCSET, 2V/Div, DC
Time : 2mS/Div
BW = 20 MHz
BW = 20 MHz
5. Over-Current Protection
No Connecting a shutdown MOSFET
Connecting a shutdown MOSFET
at OCSET Pin
(2N7002) at OCSET Pin
ROCSET=15k
APM2512
ROCSET=15k
APM2512
VOUT
1
IL
2
VOUT
1
IL
2
Ch1 : VOUT, 1V/Div, DC
Ch2 : IL, 10A/Div, DC
Ch1 : VOUT, 1V/Div, DC
Ch2 : IL, 10A/Div, DC
Time : 5mS/Div
BW = 20 MHz
Time : 5mS/Div
BW = 20 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
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APW7120
Operating Waveforms (Cont.)
(Refer to the typical application circuit, VBIAS=VIN=+12V supplied by an ATX Power Supply)
6. OCSET Voltage RC Delay
No Connecting a shutdown MOSFET
Connecting a shutdown MOSFET
at OCSET Pin
(2N7002) at OCSET Pin
VOCSET
VOCSET
IL
IL
OCP
1,2
1,2
CProber=8pF
OCP
CProber=8pF
C2N7002=44pF (measured)
Ch1 : VOCSET, 0.5V/Div, DC
Ch2 : IL, 10A/Div, DC
Ch1 : VOCSET, 0.5V/Div, DC
Ch2 : IL, 10A/Div, DC
Time : 2µS/Div
BW = 20 MHz
Time : 2µ S/Div
BW = 20 MHz
7. Short-Circuit Test
6. OCSET Voltage RC Delay (Cont.)
Connecting a shutdown MOSFET
(APM2322) at OCSET Pin
Shorted by a wire
IL
OCP
OCP
OCP
OCP
VOUT
1
UVP
VOCSET
1,2
CProber=8pF
CAPM2322 =89pF (measured)
IL
OCP
2
Ch1 : VOCSET, 0.5V/Div, DC Ch2 : IL, 10A/Div, DC
Time : 2µS/Div
BW = 20 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
11
Ch1 : VOUT, 1V/Div, DC
Ch2 : IL, 10A/Div, DC
Time : 5mS/Div
BW = 20 MHz
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APW7120
Functional Description
Please pay attention to the RC delay effect. It causes
the OCP trip level to be the function of the
operating duty. The parasitic capacitance (including
the capacitance inside the OCSET, external PCB trace
capacitance and the COSS of the shutdown MOSFET)
must be minimized, especially selecting a shutdown
MOSFET with very small COSS. The OCP trip level
follows the duty to increase a little at low operating
duty, but very much at high operating duty, like the
RC delay curve. Due to load regulation or current-limit,
heavy load normally reduces converter’s input voltage
and increases the power loses. During heavy load, the
APW7120 regulates the output voltage by expending
the duty. This rises up the OCP trip level at the same
time.
Power-On-Reset (POR)
The APW7120 monitors the VCC voltage (VCC) for
Power-On-Reset function, preventing wrong logic
operation during powering on. When the VCC voltage
is ready, the APW7120 starts a start-up process and
then ramps the output voltage up to the target voltage.
Soft-Start
The APW7120 has a built-in digital soft-start to control
the output voltage rise and limit the current surge at
the start-up. During soft-start, an internal ramp connected
to the one of the positive inputs of the Gm amplifier
rises up from 0V to 2V to replace the reference voltage
(0.8V) until the ramp voltage reaches the reference
voltage. The soft-start interval is about 3.2ms typical,
independent of the converter’s input and output
voltages.
Under-Voltage Protection (UVP)
The under-voltage function monitors the FB voltage
(VFB) to protect the converter against short-circuit
conditions. When the VFB falls below the falling UVP
threshold (67% VREF ), the APW7120 shuts off the
converter. After a preceding delay, which starts at
the beginning of the under-voltage shutdown, the
APW 7120 initiates a new soft-start to resume
regulating. The under-voltage protection shuts off
and then re-starts the converter repeatedly without
latching. The function is disabled during soft-start
process.
Over-Current Protection(OCP)
The over-current function protects the switching
conv ert er against over-current or short-circuit
conditions. The controller senses the inductor current
by detecting the drain-to-source voltage, product of
the inductor’s current and the on-resistance, of the
low-side MOSFET during it’s on-state. This method
enhances the converter’s efficiency and reduces cost
by eliminating a current sensing resistor.
A resistor (ROCSET), connected from the OCSET to the
low-side MOSFET’s drain, programs the over-current
trip level. An internal 40µA (typical) current source
flowing through the ROCSET develops a voltage (VROCSET)
across the ROCSET. When the VOCSET (VROCSET+ VDS of
the low-side MOSFET) is less than the internal overcurrent reference voltage (0.4V, typical), the IC shuts
off the converter and then initiates a new soft-start
process. After 4 over-current events are counted, the
device turns off both high-side and low-side MOSFETs
and the converter’s output is latched to be floating.
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
Over-Voltage Protection (OVP)
The over-voltage protection monitors the FB voltage to
prevent the output from over-voltage. When the output voltage rises to 118% of the nominal output voltage,
the APW7120 turns on the low-side MOSFET until
the output voltage falls below the OVP threshold,
regulating the output voltage around the OVP
thresholds.
12
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APW7120
Functional Description (Cont.)
Adaptive Shoot-Through Protection
The gate driver incorporates adaptive shoot-through
protection to high-side and low-side MOSFETs from
conducting simultaneously and shorting the input
supply. This is accomplished by ensuring the falling
gate has turned off one MOSFET before the other is
allowed to rise.
During turn-off of the low-side MOSFET, the LGATE
voltage is monitored until it reaches a 1.5V threshold,
at which time the UGATE is released to rise after a
constant delay. During turn-off of the high-side
MOSFET, the UGATE-to-PHASE voltage is also
monitored until it reaches a 1.5V threshold, at which
time the LGATE is released to rise after a constant
delay.
Shutdown Control
Pulling the OCSET voltage below 0.15V by an open
drain transistor, shown in typical application circuit,
shuts down the APW7120 PWM controller. In shutdown mode, the UGATE and LGATE are pulled to
PHASE and GND respectively, the output is floating.
Application Information
Input Capacitor Selection
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 surge current
rating.
Use small ceramic capacitors for high frequency
decoupling and bulk capacitors to supply the surge
current needed each time high-side MOSFET(Q1) turns
on. Place the small ceramic capacitors physically close
to the MOSFETs and between the drain of Q1 and the
source of low-side MOSFET(Q2).
V IN
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 largest RMS current required by the circuit. The
capacitor voltage rating should be at least 1.25 times
greater than the maximum input voltage and a voltage
rating of 1.5 times is a conservative guideline. The
RMS current of the bulk input capacitor is calculated
as the following equation :
IRMS = IOUT ⋅ D ⋅ (1 - D)
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
IQ1
UGATE
CIN
Q1
IL
IOUT
V OUT
L
LGATE
Q2
ICOUT
ESR
COUT
(A)
13
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APW7120
Application Information (Cont.)
ignored. Therefore the AC peak-to-peak output voltage
is shown below:
Input Capacitor Selection (Cont.)
T=1/FOSC
∆ V OUT = ∆ I ⋅ ESR
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. 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. The bulk
filter capacitor values are generally determined by the
ESR (Effective Series Resistance) and voltage rating
requirements rather than actual capacitance
requirements.
V UGATE
DT
I
IO U T
IL
IO U T
IQ1
I
ICOUT
V OUT
VOUT
Figure 1 Buck Converter Waveforms
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 usefulness
of these low inductance components.
Output Capacitor Selection
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 output ripple is the sum of the voltages,
having phase shift, across the ESR and the ideal output
capacitor. The peak-to-peak voltage of the ESR is calculated as the following equations :
V OUT = D ⋅ V IN
V OUT ⋅ (1 - D)
F OSC ⋅ L
V ESR = ∆ I ⋅ ESR
∆I =
(V) .......... .(5)
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. In most
cases, multiple electrolytic capacitors of small case
size perform better than a single large case capacitor.
(V) .......... . (1)
(A) .......... .(2)
(V) .......... ..(3)
Output Inductor Selection
The peak-to-peak voltage of the ideal output capacitor
is calculated as the following equations :
∆ V COUT =
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, see equations (2) and
(5). Increasing the value of inductance reduces the
ripple current and voltage. However, the large inductance
∆I
(V) ....... (4)
8 ⋅ F OSC ⋅ C OUT
For general applications using bulk capacitors, the
∆VCOUT is much smaller than the VESR and can be
Copyright  ANPEC Electronics Corp.
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APW7120
Application Information (Cont.)
dissipation, package selection and heatsink are the
dominant design factors. The power dissipation includes
two loss components, conduction loss and switching
loss. The conduction losses are the largest component
of power dissipation for both the high-side and the
low-side MOSFETs. These losses are distributed
between the two MOSFETs according to duty factor
(see the equations below). Only the high-side MOSFET
has switching losses, since the low-side MOSFETs
body diode or an external Schottky rectifier across
the lower MOSFET clamps the switching node before
the synchronous rectifier turns on. These equations
assume linear voltage-current transitions and do not
adequately model power loss due the reverse-recovery of the low-side MOSFET’s body diode. The gatecharge losses are dissipated by the APW7120 and
don’t heat the MOSFETs. However, large gate-charge
increases the switching interval, tSW which increases
the high-side MOSFET switching losses. Ensure that
both MOSFETs are within their maximum junction
temperature at high ambient temperature by calculating
the temperature rise according to package thermalresistance specifications. A separate heatsink may
be necessary depending upon MOSFET power,
package type, ambient temperature and air flow.
Output Inductor Selection (Cont.)
values reduce the converter’s response time 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 APW7120 will provide either 0% or 85%
(Average) 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.
The response time to a transient is different for
theapplication of load and the removal of load. The
following equations give the approximate response time
interval for application and removal of a transient load:
tRISE =
L ⋅ ITRAN
V IN − V OUT
,
tFALL =
L ⋅ ITRAN
V OUT
where: ITRAN is the transient load current step, tRISE is
the response time to the application of load, and tFALL
is the response time to the removal of load. The worst
case response time can be either at the application or
removal of load. Be sure to check both of these
equations at the transient load current. These requirements
are minimum and maximum output levels for the worst
case response time.
1
⋅ IOUT ⋅ VIN ⋅ tSW ⋅ FOSC
2
PLow - Side = IOUT 2 ⋅ RDSON ⋅ (1- D)
PHigh - Side = IOUT 2 ⋅ RDSON ⋅ D +
Where : tSW is the switching interval
Layout Considerations
MOSFET Selection
In high power switching regulator, a correct layout is
important to ensure proper operation of the regulator.
The APW 7120 requires two N-Channel power
MOSFETs. These should be selected based upon
R DS(ON), gate supply requirements, and thermal
management requirements.
In general, interconnecting impedances should be
minimized by using short, wide printed circuit traces.
Signal and power grounds are to be kept separate and
In high-current applications, the MOSFET power
Copyright  ANPEC Electronics Corp.
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APW7120
Application Information (Cont.)
Layout Considerations (Cont.)
5. Use an dedicated trace to connect the ROCSET
and the Drain pad of the low-side MOSFET, Kevin
connection , for accurate current sensing.
finally combined using ground plane construction or
single point grounding. Figure 2 illustrates the layout,
with bold lines indicating high current paths.
Components along the bold lines should be placed
close together. Below is a checklist for your layout:
6. Keep the switching nodes (UGATE, LGATE and
PHASE) away from sensitive small signal nodes
since these nodes are fast moving signals. Therefore
keep traces to these nodes as short as possible.
1. Begin the layout by placing the power components
first. Orient the power circuitry to chieve a clean
power flow path. If possible make all the connections
on one side of the PCB with wide, copper filled
areas.
7. Place the decoupling ceramic capacitor CHF near
the Drain of the high-side MOSFET as close as
possible. The bulk capacitors CIN are also placed
near the Drain.
2. Connect the ground of feedback divider directly
to the GND pin of the IC using a dedicated ground
trace.
8. Place the Source of the high-side MOSFET and
the Drain of the low-side MOSFET as close possible.
Minimizing the impedance with wide layout plane
between the two pads reduces the voltage bounce
of the node.
3. The VCC decoupling capacitor should be right
next to the VCC and GND pins. Capacitor CBOOT
should be connected as close to the BOOT and
PHASE pins as possible.
9. Use a wide power ground plane, with low
impedance, to connects the C HF , C IN , C OUT,
Schottky diode and the Source of the low-side
MOSFET to provide a low impedance path between
the components for large and high frequency
switching currents.
4. Minimize the length and increase the width of
the trace between UGATE/LGATE and the gates
of the MOSFETs to reduce the impedance driving
the MOSFETs.
VIN
C HF
VCC
BOOT
LGATE
5
1
CIN
+
4
APW7120
U
2
1UGATE
Q1
C OUT
Q2
PHASE 8
+
L1
VOUT
Figure 2 Recommended Layout Diagram
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APW7120
Package Information
E
e1
0.015X45
SOP-8 pin ( Reference JEDEC Registration MS-012)
H
e2
D
A1
A
1
L
0.004max.
Dim
Millimeters
Inches
Min.
Max.
Min.
Max.
A
1.35
1.75
0.053
0.069
A1
D
0.10
4.80
0.25
5.00
0.004
0.189
0.010
0.197
E
H
3.80
5.80
4.00
6.20
0.150
0.228
0.157
0.244
L
e1
0.40
0.33
1.27
0.51
0.016
0.013
0.050
0.020
e2
1.27BSC
0.50BSC
φ1
8°
8°
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APW7120
Physical Specifications
Terminal Material
Lead Solderability
Solder-Plated Copper (Solder Material : 90/10 or 63/37 SnPb), 100%Sn
Meets EIA Specification RSI86-91, ANSI/J-STD-002 Category 3.
Reflow Condition
(IR/Convection or VPR Reflow)
tp
TP
Critical Zone
T L to T P
Temperature
Ramp-up
TL
tL
Tsmax
Tsmin
Ramp-down
ts
Preheat
25
t 25 °C to Peak
Time
Classificatin Reflow Profiles
Profile Feature
Average ramp-up rate
(TL to TP)
Preheat
- Temperature Min (Tsmin)
- Temperature Max (Tsmax)
- Time (min to max) (ts)
Time maintained above:
- Temperature (TL)
- Time (tL)
Peak/Classificatioon Temperature (Tp)
Time within 5°C of actual
Peak Temperature (tp)
Ramp-down Rate
Sn-Pb Eutectic Assembly
Pb-Free Assembly
3°C/second max.
3°C/second max.
100°C
150°C
60-120 seconds
150°C
200°C
60-180 seconds
183°C
60-150 seconds
217°C
60-150 seconds
See table 1
See table 2
10-30 seconds
20-40 seconds
6°C/second max.
6°C/second max.
6 minutes max.
8 minutes max.
Time 25°C to Peak Temperature
Notes: All temperatures refer to topside of the package .Measured on the body surface.
Copyright  ANPEC Electronics Corp.
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APW7120
Classification Reflow Profiles (Cont.)
Table 1. SnPb Entectic Process – Package Peak Reflow Temperatures
3
Package Thickness
Volume mm
<350
<2.5 mm
240 +0/-5°C
≥2.5 mm
225 +0/-5°C
3
Volume mm
≥350
225 +0/-5°C
225 +0/-5°C
Table 2. Pb-free Process – Package Classification Reflow Temperatures
Package Thickness
Volume mm3
Volume mm3
Volume mm3
<350
350-2000
>2000
<1.6 mm
260 +0°C*
260 +0°C*
260 +0°C*
1.6 mm – 2.5 mm
260 +0°C*
250 +0°C*
245 +0°C*
≥2.5 mm
250 +0°C*
245 +0°C*
245 +0°C*
*Tolerance: The device manufacturer/supplier shall assure process compatibility up to and including the
stated classification temperature (this means Peak reflow temperature +0°C. For example 260°C+0°C)
at the rated MSL level.
Reliability Test Program
Test item
SOLDERABILITY
HOLT
PCT
TST
ESD
Latch-Up
Method
MIL-STD-883D-2003
MIL-STD-883D-1005.7
JESD-22-B,A102
MIL-STD-883D-1011.9
MIL-STD-883D-3015.7
JESD 78
Description
245°C, 5 SEC
1000 Hrs Bias @125°C
168 Hrs, 100%RH, 121°C
-65°C~150°C, 200 Cycles
VHBM > 2KV, VMM > 200V
10ms, 1tr > 100mA
Carrier Tape & Reel Dimensions
t
D
P
Po
E
P1
Bo
F
W
Ko
Ao
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
D1
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APW7120
Carrier Tape & Reel Dimensions (Cont.)
T2
J
C
A
B
T1
Reel Dimensions
Application
A
330 ± 1
SOP- 8
F
5.5± 1
B
C
62 +1.5 12.75+ 0.15
D
J
T1
T2
W
P
E
2 ± 0.5
12.4 ± 0.2
2 ± 0.2
12± 0. 3
8± 0.1
1.75±0.1
Po
P1
Ao
Bo
Ko
t
2.0 ± 0.1
6.4 ± 0.1
5.2± 0. 1
D1
1.55 +0.1 1.55+ 0.25 4.0 ± 0.1
2.1± 0.1 0.3±0.013
(mm)
Cover Tape Dimensions
Application
SOP- 8
Carrier Width
12
Cover Tape Width
9.3
Devices Per Reel
2500
Customer Service
Anpec Electronics Corp.
Head Office :
No.6, Dusing 1st Road, SBIP,
Hsin-Chu, Taiwan, R.O.C.
Tel : 886-3-5642000
Fax : 886-3-5642050
Taipei Branch :
7F, No. 137, Lane 235, Pac Chiao Rd.,
Hsin Tien City, Taipei Hsien, Taiwan, R. O. C.
Tel : 886-2-89191368
Fax : 886-2-89191369
Copyright  ANPEC Electronics Corp.
Rev. A.4 - Jan., 2006
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