ANPEC APW7120A_09

APW7120A
5V to 12V Supply Voltage, 8-PIN, Synchronous Buck PWM Controller
Features
General Description
•
Operating with Single 5~12V Supply Voltage or
The APW7120A is a fixed 300kHz frequency, voltage mode,
Two Supply Voltages
and synchronous PWM controller. The device drives two
low cost N-channel MOSFETs and is designed to work
•
Drive Dual Low Cost N-Channel MOSFETs
with single 5~12V or two supply voltage(s), providing excellent regulation for load transients.
- Adaptive Shoot-Through Protection
•
Built-in Feedback Compensation
The APW7120A integrates controls, monitoring and protection functions into a single 8-pin package to provide a
- Voltage-Mode PWM Control
- 0~100% Duty Ratio
low cost and perfect power solution.
A power-on-reset (POR) circuit monitors the VCC supply
- Fast Transient Response
•
±2% 0.8V Reference
voltage to prevent wrong logic controls. An internal 0.8V
reference provides low output voltage down to 0.8V for
- Over Line, Load Regulation, and Operating
further applications. An built-in digital soft-start with fixed
soft-start interval prevents the output voltage from over-
Temperature
•
•
•
•
•
Programmable Over-Current Protection
shoot as well as limiting the input current. The controller’s
over-current protection monitors the output current by
- Using RDS(ON) of Low-Side MOSFET
Hiccup-Mode Under-Voltage Protection
using the voltage drop across the low-side MOSFET’s
RDS(ON), eliminating the need of a current sensing resistor.
118% Over-Voltage Protection
Adjustable Output Voltage
Additional under voltage and over voltage protections
monitor the voltage on FB pin for short-circuit and over-
Small Converter Size
- 300kHz Constant Switching Frequency
voltage protections. The over-current protection cycles the
soft-start function until 4 over-current events are counted.
- Small SOP-8 Package
•
•
•
Pulling and holding the voltage on OCSET pin below
0.15V with an open drain device shuts down the controller.
Built-In Digital Soft-Start
Shutdown Control Using an External MOSFET
Lead Free and Green Devices Available
Pin Cinfiguration
(RoHS Compliant)
Applications
•
•
•
Motherboard
Graphics Card
High Current, Up to 20A, DC-DC Converters
BOOT 1
8 PHASE
UGATE 2
7 OCSET
GND 3
LGATE 4
5 VCC
6 FB
SOP-8
(Top View)
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.3 - Nov., 2009
1
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APW7120A
Ordering and Marking Information
APW7120A
Package Code
K : SOP-8
Operating Ambient Temperature Range
E : -20 to 70 oC
Handling Code
TR : Tape & Reel
Assembly Material
G : Halogen and Lead Free Device
Assembly Material
Handling Code
Temperature Range
Package Code
APW7120A K :
APW7120A
XXXXX
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. ANPEC lead-free products meet or exceed the lead-free requirements of IPC/JEDEC J-STD-020D for
MSL classification at lead-free peak reflow temperature. ANPEC defines “Green” to mean lead-free (RoHS compliant) and halogen
free (Br or Cl does not exceed 900ppm by weight in homogeneous material and total of Br and Cl does not exceed 1500ppm by
weight).
Absolute Maximum Ratings
Symbol
VCC
VBOOT
(Note 1)
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
-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)
-0.3 ~ 7
Maximum Junction Temperature
TSTG
TSDR
Storage Temperature
Maximum Lead Soldering Temperature, 10 Seconds
V
150
o
-65 ~ 150
o
260
o
C
C
C
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.
Thermal Characteristics
Symbol
θJA
Parameter
Typical Value
Junction-to-Ambient Resistance in Free Air
(Note 2)
SOP-8
160
Unit
o
C/W
Note 2: θJA is measured with the component mounted on a high effective thermal conductivity test board in free air.
Copyright  ANPEC Electronics Corp.
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APW7120A
Recommended Operating Conditions (Note 3)
Symbol
Parameter
VCC
VCC Supply Voltage
VOUT
Converter Output Voltage
VIN
Converter Input Voltage
IOUT
Converter Output Current
TA
Ambient Temperature
TJ
Range
Unit
4.5 ~ 13.2
V
0.8 ~ 70%VIN
V
2.2 ~ 13.2
V
0 ~ 20
Junction Temperature
A
-20 ~ 70
o
-20 ~ 125
o
C
C
Note 3: Please refer to the typical application circuit.
Electrical Characteristics
Unless otherswise specified, these specifications apply over VCC = 12V, VBOOT = 12V and TA = -20 ~ 70oC. Typical values
are at TA = 25oC.
Symbol
Parameter
Test Conditions
APW7120A
Unit
Min.
Typ.
Max.
-
2.1
6
mA
-
1.5
4
mA
SUPPLY CURRENT
IVCC
VCC Nominal Supply Current
UGATE and LGATE Open
VCC Shutdown Supply Current
POWER-ON-RESET
Rising VCC Threshold
3.8
4.1
4.4
V
Hysteresis
0.1
0.45
0.6
V
250
300
350
kHz
-
1.5
-
VP-P
-
0.8
-
V
OSCILLATOR
FOSC
∆VOSC
Free Running Frequency
Ramp Amplitude
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
%
-
86
-
dB
ERROR AMPLIFIER
DC Gain
FP1
First Pole Frequency
-
0.4
-
Hz
FZ
Zero Frequency
-
0.4
-
kHz
FP2
Second Pole Frequency
-
430
-
kHz
Average UGATE Duty Range
0
-
70
%
FB Input Current
-
-
0.1
µA
1.0
2.0
-
A
PWM CONTROLLER GATE DRIVERS
UGATE Source
TD
VBOOT-PHASE =12V, VUGATE-PHASE =6V
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
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APW7120A
Electrical Characteristics (Cont.)
Unless otherswise specified, these specifications apply over VCC = 12V, VBOOT = 12V and TA = -20 ~ 70oC. Typical values
are at TA = 25oC.
Symbol
Parameter
Test Conditions
APW7120A
Min.
Typ.
Max.
35
40
45
Unit
PROTECTIONS
IOCSET
UVFB
OCSET Current Source
VPHASE=0V, Normal Operation
µA
Over-Current Reference Voltage
TA =-20~70°C
0.37
0.4
0.43
V
FB Under-Voltage Threshold
VFB Falling
62
67
72
%
-
45
-
mV
VFB Rising
114
118
122
%
2
3.8
5
ms
Falling VOCSET
0.1
0.15
0.3
V
-
40
-
mV
FB Under-Voltage Hysteresis
Over-Voltage Threshold
SOFT-START AND SHUTDOWN
TSS
Soft-Start Interval
OCSET Shutdown Threshold
OCSET Shutdown Hysteresis
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APW7120A
Typical Operating Characteristics
Reference Voltage vs. Junction
350
Switching Frequency, FOSC (kHz)
Reference Voltage, VREF (V)
Temperature
0.812
0.810
0.808
0.806
0.804
0.802
0.800
0.798
0.796
0.794
0.792
0.790
0.788
-50
-25
0
25
50 75 100
Junction Temperature (oC)
340
330
320
310
300
290
280
270
260
250
-50
125 150
Switching Frequency vs. Junction
Temperature
-25
0
25 50 75 100 125 150
Junction Temperature (oC)
VCC POR Threshold Voltage vs.
Junction Temperature
45
4.4
44
4.3
VCC POR Threshold Voltage (V)
OCSET Current, IOCSET (µA)
OCSET Current vs. Junction Temperature
43
42
41
40
39
38
37
36
35
-50
-25
4.2
4.0
3.9
3.8
Falling VCC
3.7
3.6
3.5
3.4
-50
0
25 50 75 100 125 150
Junction Temperature (oC)
Rising VCC
4.1
-25
0
25
50
75 100 125 150
Junction Temperature (oC)
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)
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APW7120A
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 = ±7.5A/µs
IOUT = 0A -> 15A
IOUT = 0A -> 15A -> 0A
IOUT = 15A -> 0A
VOUT=1.8V
VOUT
VOUT
1
1
1
VOUT
VUGATE
VUGATE
3
3
VUGATE
3
15A
IOUT
Ch1 : VOUT, 100mV/Div, AC,
Ch2 : IOUT, 10A/Div
Ch3 : VUGATE, 20V/Div, DC
Time : 5µs/Div
BW = 20 MHz
IOUT
0A
2
2
Ch1 : VOUT, 100mV/Div, AC,
Ch2 : IOUT, 10A/Div
Ch3 : VUGATE, 20V/Div, DC
Time : 40µs/Div
BW = 20 MHz
IOUT
2
Ch1 : VOUT, 100mV/Div, AC,
Ch2 : IOUT, 10A/Div
Ch3 : VUGATE, 20V/Div, DC
Time : 5µs/Div
BW = 20 MHz
2. UGATE and LGATE Switching Waveforms
Rising VUGATE
Falling VUGATE
IOUT = 15A
VLGATE
VUGATE
VLGATE
VUGATE
1,2
1,2
Ch1 : VUGATE, 5V/Div, DC
Time : 20ns/Div
Ch2 : VLGATE, 2V/Div, DC
BW = 500 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
Ch1 : VUGATE, 5V/Div, DC Ch2 : VLGATE, 2V/Div, DC
Time : 20ns/Div
BW = 500 MHz
6
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APW7120A
Operating Waveforms (Cont.)
(Refer to the typical application circuit, VBIAS=VIN=+12V supplied by an ATX Power Supply)
3. Powering ON / OFF
Powering ON
VCC=VIN=5V
RL=0.12Ω
Powering OFF
VCC
VCC=VIN=5V
RL=0.12Ω
VCC
1
1
IL
IL
3
3
VOUT
2
VOUT
2
Ch1 : VCC, 2V/Div, DC
Ch3 : IL, 10A/Div, DC
BW = 20 MHz
Ch2 : VOUT, 1V/Div, DC
Time : 5ms/Div
Ch1 : VCC, 2V/Div, DC
Ch3 : IL, 10A/Div, DC
BW = 20 MHz
Powering ON
VCC=VIN=12V
RL=0.12Ω
Ch2 : VOUT, 1V/Div, DC
Time : 10ms/Div
Powering OFF
VCC=VIN=12V
RL=0.12Ω
VCC
VCC
1
1
IL
IL
3
3
VOUT
VOUT
2
2
Ch1 : VCC, 5V/Div, DC
Ch3 : IL, 10A/Div, DC
BW = 20 MHz
Ch1 : VCC, 5V/Div, DC
Ch3 : IL, 10A/Div, DC
BW = 20 MHz
Ch2 : VOUT, 1V/Div, DC
Time : 5ms/Div
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Ch2 : VOUT, 1V/Div, DC
Time : 10ms/Div
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APW7120A
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
BW = 20 MHz
Ch1 : VOUT, 1V/Div, DC
Ch3 : VOCSET, 2V/Div, DC
BW = 20 MHz
Ch2 : VUGATE, 20V/Div, DC
Time : 2ms/Div
5. Over-Current Protection
No Connecting a shutdown MOSFET
at OCSET Pin
Connecting a shutdown MOSFET
(2N7002) at OCSET Pin
ROCSET=15k
APM2512
ROCSET=15k
APM2512
VOUT
1
IL
2
Ch1 : VOUT, 1V/Div, DC
Time : 5ms/Div
IL
2
Ch2 : IL, 10A/Div, DC
BW = 20 MHz
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
VOUT
1
Ch1 : VOUT, 1V/Div, DC
Time : 5ms/Div
8
Ch2 : IL, 10A/Div, DC
BW = 20 MHz
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APW7120A
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
at OCSET Pin
Connecting a shutdown MOSFET
(2N7002) at OCSET Pin
VOCSET
VOCSET
IL
IL
OCP
1,2
1,2
CProber=8pF
Ch1 : VOCSET, 0.5V/Div, DC
Time : 2µS/Div
Ch2 : IL, 10A/Div, DC
BW = 20 MHz
OCP
CProber=8pF
C2N7002=44pF (measured)
Ch1 : VOCSET, 0.5V/Div, DC
Time : 2µ S/Div
Ch2 : IL, 10A/Div, DC
BW = 20 MHz
7. Short-Circuit Test
6. OCSET Voltage RC Delay
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
BW = 20 MHz
Time : 2µS/Div
Copyright  ANPEC Electronics Corp.
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Ch1 : VOUT, 1V/Div, DC
Time : 5ms/Div
9
Ch2 : IL, 10A/Div, DC
BW = 20 MHz
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APW7120A
Pin Description
PIN
FUNCTION
NO.
NAME
1
BOOT
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.
2
UGATE
Connect this pin to the high-side N-channel MOSFET gate. This pin provides gate drive for the high-side
MOSFET.
3
GND
The GND terminal provides return path for the IC bias current and the low-side MOSFET driver pull-low
current. Connect the pin to the system ground via very low impedance layout on PCBs.
4
LGATE
Connect this pin to the low-side N-channel MOSFET gate. This pin provides gate drive for the low-side
MOSFET.
5
VCC
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.
FB
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 closed-loop operation. The output voltage set by the resistor
divider is determined using the following formula:
R1
VOUT = 0.8V ⋅ ( 1 +
)
(V)
R2
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.
6
The OCSET is a dual-function input pin for over-current protection and shutdown control. Connect a
resistor (ROCSET) from this pin to the Drain of the low-side MOSFET. This resistor, an internal 40µA current
source (IOCSET), and the MOSFET on-resistance (RDSON) set the converter over-current trip level (IPEAK)
according to the following formula:
7
OCSET
IPEAK =
40µA ⋅ ROCSET - 0.4V
RDSON
(A)
Pulling and holding this pin below 0.15V with an open 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.
8
PHASE
The pin provides return path for the high-side MOSFET driver pull-low current. Connect this pin to the
high-side MOSFET source.
Copyright  ANPEC Electronics Corp.
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APW7120A
Block Diagram
VCC
3VCC
40µA
OCSET
Power-OnReset
Regulator
POR
3VCC
67%VREF
0.4V
OC
2.5V
Enable
0.15V
Soft-Start
and Fault
Logic
UV
BOOT
OV
UGATE
118%VREF
Inhibit
Soft-Start
PHASE
Gate
Control
COMP
FB
PWM
VREF
0.8V
VCC
Gm
Amplifier
LGATE
FOSC
300kHz
GND
Oscillator
Typical Application Circuit
L1
1µH
D1
1N4148
VBIAS
VIN
+5V/12V
C5
1µF
C2
0.1µF
1
C3, C4
820µF x2
+5/12V
BOOT
R4
2.2
UGATE
5
C1
1µF
PHASE
VCC
U1 OCSET
APW7120A
6
LGATE
FB
Q1
APM2512
2
8
7
L2
1.5µH
R5
VOUT
C6, C7
1000µF x2
1.8V/15A
Q2
APM2512
4
GND
3
Shutdown
R1
1.5k
Q3
2N7002
R2
1.2k
C8
0.1µF
R3
200
C3, C4 : 820µF/16V , ESR=25mΩ
C6, C7 : 1000µF/6.3V, ESR=30mΩ
Copyright  ANPEC Electronics Corp.
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APW7120A
Function Description
Power-On-Reset (POR)
at low operating duty, but very much at high operating
duty, like the RC delay curve. Due to load regulation or
The APW7120A monitors the VCC voltage (VCC) for PowerOn-Reset function, preventing wrong logic operation dur-
current-limit, heavy load normally reduces converter’s
input voltage and increases the power loses. During heavy
ing powering on. When the VCC voltage is ready, the
APW7120A starts a start-up process and then ramps the
load, the APW7120A regulates the output voltage by expending the duty. This rises up the OCP trip level at the
output voltage up to the target voltage.
same time.
Soft-Start
Under-Voltage Protection (UVP)
The APW7120A has a built-in digital soft-start to control
The under-voltage function monitors the FB voltage (VFB)
to protect the converter against short-circuit conditions.
the output voltage rise and limit the current surge at the
start-up. During soft-start, an internal ramp connected to
When the VFB falls below the falling UVP threshold (67%
VREF), the APW7120A shuts off the converter. After a pre-
the one of the positive inputs of the Gm amplifier rises up
from 0V to 2V to replace the reference voltage (0.8V) until
ceding delay, which starts at the beginning of the undervoltage shutdown, the APW7120A initiates a new soft-
the ramp voltage reaches the reference voltage. The softstart interval is about 3.2ms typical, independent of the
start to resume regulating. The under-voltage protection
shuts off and then re-starts the converter repeatedly with-
converter’s input and output voltages.
Over-Current Protection (OCP)
out latching. The function is disabled during soft-start
process.
The over-current function protects the switching converter
against over-current or short-circuit conditions. The controller senses the inductor current by detecting the drain-
Over-Voltage Protection (OVP)
The over-voltage protection monitors the FB voltage to
prevent the output from over-voltage. When the output
to-source voltage, product of the inductor’s current and
the on-resistance, of the low-side MOSFET during it’s on-
voltage rises to 118% of the nominal output voltage, the
APW7120A turns on the low-side MOSFET until the out-
state. This method enhances the converter’s efficiency
and reduces cost by eliminating a current sensing
put voltage falls below the OVP threshold, regulating the
output voltage around the OVP thresholds.
resistor.
A resistor (ROCSET), connected from the OCSET to the lowside MOSFET’s drain, programs the over-current trip level.
An internal 40µA (typical) current source flowing through
Adaptive Shoot-Through Protection
The gate driver incorporates adaptive shoot-through pro-
the ROCSET develops a voltage (VROCSET) across the ROCSET.
When the VOCSET (VROCSET+ VDS of the low-side MOSFET) is
tection to high-side and low-side MOSFETs from conducting simultaneously and shorting the input supply. This
less than the internal over-current reference voltage (0.
4V, typical), the IC shuts off the converter and then ini-
is accomplished by ensuring the falling gate has turned
off one MOSFET before the other is allowed to rise.
tiates a new soft-start process. After 4 over-current events
are counted, the device turns off both high-side and low-
During turn-off of the low-side MOSFET, the LGATE voltage is monitored until it reaches a 1.5V threshold, at which
side MOSFETs and the converter’s output is latched to be
floating.
time the UGATE is released to rise after a constant delay.
During turn-off of the high-side MOSFET, the UGATE-to-
Please pay attention to the RC delay effect. It causes
the OCP trip level to be the function of the operating
PHASE voltage is also monitored until it reaches a 1.5V
threshold, at which time the LGATE is released to rise
duty. The parasitic capacitance (including the capacitance
inside the OCSET, external PCB trace capacitance and
after a constant delay.
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
Copyright  ANPEC Electronics Corp.
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APW7120A
Function Description (Cont.)
Shutdown Control
Pulling the OCSET voltage below 0.15V by an open drain
transistor, shown in typical application circuit, shuts down
the APW7120A PWM controller. In shutdown mode, the
UGATE and LGATE are pulled to PHASE and GND
respectively, the output is floating.
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APW7120A
Application Information
T=1/FOSC
Input Capacitor Selection
Use small ceramic capacitors for high frequency
decoupling and bulk capacitors to supply the surge cur-
VUGATE
rent needed each time high-side MOSFET(Q1) turns on.
Place the small ceramic capacitors physically close to the
DT
I
IOUT
MOSFETs and between the drain of Q1 and the source of
low-side MOSFET(Q2).
IL
IOUT
The important parameters for the bulk input capacitor are
the voltage rating and the RMS current rating. For reliable
IQ1
operation, select the bulk capacitor with voltage and current ratings above the maximum input voltage and larg-
ICOUT
I
VOUT
est 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
VOUT
Figure 1. Buck Converter Waveforms
input capacitor is calculated as the following equation :
IRMS = IOUT ⋅ D ⋅ (1- D)
(A)
Output Capacitor Selection
An output capacitor is required to filter the output and sup-
For a through hole design, several electrolytic capacitors
may be needed. For surface mount designs, solid tanta-
ply the load transient current. The filtering requirements
are a function of the switching frequency and the ripple
lum capacitors can be used, but caution must be exercised with regard to the capacitor surge current rating.
current. The output ripple is the sum of the voltages, having phase shift, across the ESR and the ideal output
VIN
IQ1
UGATE
Q1
IL
Q2
VOUT = D ⋅ VIN
VOUT ⋅ (1 - D)
∆I =
FOSC ⋅ L
VESR = ∆ I ⋅ ESR
IOUT
VOUT
L
LGATE
capacitor. The peak-to-peak voltage of the ESR is calculated as the following equations :
CIN
ICOUT
ESR
(V) .......... . (1)
(A) .......... .(2)
(V) .......... ..(3)
The peak-to-peak voltage of the ideal output capacitor is
COUT
calculated as the following equation :
∆VCOUT =
∆I
(V) ....... (4)
8 ⋅ FOSC ⋅ COUT
For general applications using bulk capacitors, the ∆VCOUT
is much smaller than the V ESR and can be ignored.
Therefore, the AC peak-to-peak output voltage is shown
below:
∆VOUT = ∆ I ⋅ ESR
(V) ...........(5)
The load transient requirements are the 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
Copyright  ANPEC Electronics Corp.
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APW7120A
Application Information (Cont.)
Output Capacitor Selection (Cont.)
tions give the approximate response time interval for application and removal of a transient load:
above 1A/ns. High frequency capacitors initially supply
the transient and slow the current load rate seen by the
tRISE =
L ⋅ ITRAN
L ⋅ ITRAN
, tFALL =
VIN − VOUT
VOUT
bulk capacitors. The bulk filter capacitor values are generally determined by the ESR (Effective Series Resistance)
where
and voltage rating requirements rather than actual capacitance requirements.
ITRAN is the transient load current step, tRISE is the response
time to the application of load, and tFALL is the response
High frequency decoupling capacitors should be placed
as close to the power pins of the load as physically
time to the removal of load. The worst case response
time can be either at the application or removal of load.
possible. Be careful not to add inductance in the circuit
board wiring that could cancel the usefulness of these
Be sure to check both of these equations at the transient
load current. These requirements are minimum and
low inductance components.
An aluminum electrolytic capacitor’s ESR value is related
maximum output levels for the worst case response time.
MOSFET Selection
to the case size with lower ESR available in larger case
sizes. However, the Equivalent Series Inductance (ESL)
In high-current applications, the MOSFET power
dissipation, package selection and heatsink are the domi-
of these capacitors increases with case size and can reduce the usefulness of the capacitor to high slew-rate
nant design factors. The power dissipation includes two
loss components, conduction loss and switching loss.
transient loading. In most cases, multiple electrolytic capacitors of small case size perform better than a single
The conduction losses are the largest component of
power dissipation for both the high-side and the low-side
large case capacitor.
MOSFETs. These losses are distributed between the two
Output Inductor Selection
The output inductor is selected to meet the output voltage
MOSFETs according to duty factor (see the equations
below). Only the high-side MOSFET has switching losses,
ripple requirements and minimize the converter’s response time to the load transient. The inductor value de-
since the low-side MOSFETs body diode or an external
Schottky rectifier across the lower MOSFET clamps the
termines the converter’s ripple current and the ripple
voltage, see equations (2) and (5). Increasing the value of
switching node before the synchronous rectifier turns on.
These equations assume linear voltage-current transi-
inductance reduces the ripple current and voltage.
However, the large inductance values reduce the
tions and do not adequately model power loss due the
reverse-recovery of the low-side MOSFET’s body diode.
converter’s response time to a load transient.
One of the parameters limiting the converter’s response
The gate-charge losses are dissipated by the APW7120A
and don’t heat the MOSFETs. However, large gate-charge
to a load transient is the time required to change the inductor current. Given a sufficiently fast control loop design,
increases the switching interval, tSW which increases the
high-side MOSFET switching losses. Ensure that both
the APW7120A will provide either 0% or 85%(Average)
duty cycle in response to a load transient. The response
MOSFETs are within their maximum junction temperature at high ambient temperature by calculating the tem-
time is the time required to slew the inductor current from
an initial current value to the transient current level. Dur-
perature rise according to package thermal-resistance
specifications. A separate heatsink may be necessary
ing this interval the difference between the inductor current and the transient current level must be supplied by
depending upon MOSFET power, package type, ambient
temperature and air flow.
PHigh - Side = IOUT 2 ⋅ RDSON ⋅ D +
the output capacitor. Minimizing the response time can
minimize the output capacitance required.
PLow - Side = IOUT 2 ⋅ RDSON ⋅ (1 - D)
The response time to a transient is different for the application of load and the removal of load. The following equa-
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
1
⋅ IOUT ⋅ VIN ⋅ tSW ⋅ FOSC
2
Where
tSW is the switching interval
15
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APW7120A
Application Information (Cont.)
Feedback Compensation
quencies of the A1(S), A2(S), A3(S), and ACL(S) are shown
or calculated as the following equations:
The figure 2 shows the control system of the APW7120,
which consists of an internal voltage-mode PW M
FZA21 = 0.4kHz
FPA21 = 430kHz (FP2)
1
F PA41,2 =
2 π x LC
modulator, an output L-C filter, a resistor-divider and an
internal compensation network. The R and C are the
equivalent series resistance (ESR) and capacitance of
the output capacitor; the L is the inductance of the output
F ZA41 =
inductor.
VIN
APW7120
L
the input voltage of the PWM converter and the load resistance of the converter is very large. For good converter
R VO
Driver
LGATE
FB
Internal
Compensation
Network
Zero frequencies of the A2(S), the FPA41,2 and FZA41 are the
double-Pole and Zero frequencies of the A4(S), the VIN is
VOUT
VPHASE
VCOMP
stability, the values of the L, C, and R must be selected to
meet the following criteria:
C
VFB
1
2 π xRxC
where the FPA21 (or FP2) and FZA21 (or Fz) are the Pole and
UGATE
VOSC=1.6V
(FZ)
1. Make sure the double-pole frequency (FPA41,2) of the
output filter is bigger than the zero frequency (FZA21) of
R1
the internal compensation network.
2. The following equation must be true:
R2
0.8V
log(
Figure 2. APW7120 Control System
3. The converter crossover frequency (FCO) must be in the
range of 10%~30% of minimum FOSC of the converter.
The FCO is calculated by using the following equations:
The transfer functions are defined as following:
A1(S) =
VFB(S)
R2
=
VO(S) R1 + R2
A2(S) =
VCOMP(S)
(Internal Compensation)
VFB(S)
VIN
R2
1 L
) + log(
) − 2 ⋅ log( ⋅
) + 1.2 > 0
∆VOSC
R1 + R2
R C
Gain at FZA41


20
10% FOSC_MIN ≤  FCO = 10
⋅ FZA41 ≤ 30% FOSC_MIN




VIN
R2
Gain at FZA41 = 20 ⋅ log(
) + 20 ⋅ log(
)
∆VOSC
R1 + R2
VPHASE(S)
VIN
=
VCOMP(S) ∆VOSC
VOUT(S)
R ⋅C⋅S +1
A4(S) =
=
VPHASE(S) L ⋅ C ⋅ S2 + R ⋅ C ⋅ S + 1
A3(S) =
− 40 ⋅ log(
1 L
⋅
) + 27
R C
4. The values of L, C, and R selected must meet the
VOUT(S)
VO(S)
VFB(S) VCOMP(S) VPHASE(S) VOUT (S)
=
⋅
⋅
⋅
VO(S)
VFB(S)
VCOMP(S) VPHASE(S)
= A1(S) ⋅ A2(S) ⋅ A3(S) ⋅ A4(S)
ACL(S) =
equations above over the operaing temperature,
voltage, and current ranges.
where A1(S) is the transfer function of the resistor-divider,
A2(S) is the transfer function of the feedback compensation network, A3(S) is the transfer function of the PWM
modulator, A4(S) is the transfer function of the output LC
filter, and ACL(S) is the transfer function of the closed-loop
control system. Refer to figure 3. The Pole and Zero freCopyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
16
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APW7120A
Application Information (Cont.)
6. Keep the switching nodes (UGATE, LGATE, and PHASE)
away from sensitive small signal nodes since these
Feedback Compensation (Cont.)
100
nodes are fast moving signals. Therefore, keep traces
to these nodes as short as possible.
80
Gain (dB)
60
FZA21
7. Place the decoupling ceramic capacitor CHF near the
Drain of the high-side MOSFET as close as possible.
Compensation Gain
40
20
0
FPA41,2
-20
FCO
FZA41
The bulk capacitors CIN are also placed near the Drain.
8. Place the Source of the high-side MOSFET and the
FPA21
Converter Gain
Drain of the low-side MOSFET as close as possible.
Minimizing the impedance with wide layout plane be-
-40
-60
100
PWM &Filter Gain
1K
10K
100K
1M
tween the two pads reduces the voltage bounce of the
node.
10M
Frequency (f, Hz)
9. Use a wide power ground plane, with low impedance,
to connects the CHF, CIN, COUT, Schottky diode and the
Figure 3. Converter Gain vs. Frequency
Source of the low-side MOSFET to provide a low impedance path between the components for large and
Layout Consideration
high frequency switching currents.
In high power switching regulator, a correct layout is important to ensure proper operation of the regulator.
CHF
In general, interconnecting impedances should be minimized by using short, wide printed circuit traces. Signal
and power grounds are to be kept separate and finally
combined using ground plane construction or single point
VCC
grounding. Figure 4 illustrates the layout, with bold lines
indicating high current paths. Components along the bold
BOOT
lines should be placed close together. Below is a checklist for your layout:
LGATE
PHASE 8
path. If possible, make all the connections on one side
of the PCB with wide, copper filled areas.
+
4
APW7120A
U
2
1 UGATE
1. Begin the layout by placing the power components first.
Orient the power circuitry to chieve a clean power flow
CIN
5
1
VIN
Q1
Q2
+
L1
COUT
VOUT
Figure 4. Recommended Layout Digram
2. Connect the ground of feedback divider directly to the
GND pin of the IC using a dedicated ground trace.
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.
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.
5. Use an dedicated trace to connect the ROCSET and the
Drain pad of the low-side MOSFET, Kevin connection,
for accurate current sensing.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
17
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APW7120A
Package Information
SOP-8
D
E
E1
SEE VIEW A
h X 45
°
c
A
0.25
b
GAUGE PLANE
SEATING PLANE
A1
A2
e
L
VIEW A
S
Y
M
B
O
L
SOP-8
INCHES
MILLIMETERS
MIN.
MAX.
MIN.
MAX.
1.75
A
0.069
0.010
0.004
0.25
A1
0.10
A2
1.25
b
0.31
0.51
0.012
0.020
c
0.17
0.25
0.007
0.010
D
4.80
5.00
0.189
0.197
E
5.80
6.20
0.228
0.244
E1
3.80
4.00
0.150
0.157
e
0.049
1.27 BSC
0.050 BSC
h
0.25
0.50
0.010
0.020
L
0.40
1.27
0.016
0.050
0
0°
8°
0°
8°
Note: 1. Follow JEDEC MS-012 AA.
2. Dimension “D” does not include mold flash, protrusions or gate burrs.
Mold flash, protrusion or gate burrs shall not exceed 6 mil per side.
3. Dimension “E” does not include inter-lead flash or protrusions.
Inter-lead flash and protrusions shall not exceed 10 mil per side.
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
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APW7120A
Carrier Tape & Reel Dimensions
P0
P2
P1
A
B0
W
F
E1
OD0
K0
A0
A
OD1 B
B
T
SECTION A-A
SECTION B-B
H
A
d
T1
Application
A
H
T1
C
d
D
W
E1
F
330.0±2.00
50 MIN.
12.4+2.00
-0.00
13.0+0.50
-0.20
1.5 MIN.
20.2 MIN.
12.0±0.30
1.75±0.10
5.5±0.05
P0
P1
P2
D0
D1
T
A0
B0
K0
2.0±0.05
1.5+0.10
-0.00
1.5 MIN.
0.6+0.00
-0.40
6.40±0.20
5.20±0.20
2.10±0.20
SOP-8
4.0±0.10
8.0±0.10
(mm)
Devices Per Unit
Package Type
Unit
Quantity
SOP-8
Tape & Reel
2500
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Rev. A.3 - Nov., 2009
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APW7120A
Taping Direction Information
SOP-8
USER DIRECTION OF FEED
Classification Profile
Copyright  ANPEC Electronics Corp.
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APW7120A
Classification Reflow Profiles
Profile Feature
Sn-Pb Eutectic Assembly
Pb-Free Assembly
100 °C
150 °C
60-120 seconds
150 °C
200 °C
60-120 seconds
3 °C/second max.
3°C/second max.
183 °C
60-150 seconds
217 °C
60-150 seconds
See Classification Temp in table 1
See Classification Temp in table 2
Time (tP)** within 5°C of the specified
classification temperature (Tc)
20** seconds
30** seconds
Average ramp-down rate (Tp to Tsmax)
6 °C/second max.
6 °C/second max.
6 minutes max.
8 minutes max.
Preheat & Soak
Temperature min (Tsmin)
Temperature max (Tsmax)
Time (Tsmin to Tsmax) (ts)
Average ramp-up rate
(Tsmax to TP)
Liquidous temperature (TL)
Time at liquidous (tL)
Peak package body Temperature
(Tp)*
Time 25°C to peak temperature
* Tolerance for peak profile Temperature (Tp) is defined as a supplier minimum and a user maximum.
** Tolerance for time at peak profile temperature (tp) is defined as a supplier minimum and a user maximum.
Table 1. SnPb Eutectic Process – Classification Temperatures (Tc)
Package
Thickness
<2.5 mm
≥2.5 mm
Volume mm
<350
235 °C
220 °C
3
Volume mm
≥350
220 °C
220 °C
3
Table 2. Pb-free Process – Classification Temperatures (Tc)
Package
Thickness
<1.6 mm
1.6 mm – 2.5 mm
≥2.5 mm
Volume mm
<350
260 °C
260 °C
250 °C
3
Volume mm
350-2000
260 °C
250 °C
245 °C
3
Volume mm
>2000
260 °C
245 °C
245 °C
3
Reliability Test Program
Test item
SOLDERABILITY
HOLT
PCT
TCT
HBM
MM
Latch-Up
Copyright  ANPEC Electronics Corp.
Rev. A.3 - Nov., 2009
Method
JESD-22, B102
JESD-22, A108
JESD-22, A102
JESD-22, A104
MIL-STD-883-3015.7
JESD-22, A115
JESD 78
21
Description
5 Sec, 245°C
1000 Hrs, Bias @ 125°C
168 Hrs, 100%RH, 2atm, 121°C
500 Cycles, -65°C~150°C
VHBM≧2KV
VMM≧200V
10ms, 1tr≧100mA
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APW7120A
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 :
2F, No. 11, Lane 218, Sec 2 Jhongsing Rd.,
Sindian City, Taipei County 23146, Taiwan
Tel : 886-2-2910-3838
Fax : 886-2-2917-3838
Copyright  ANPEC Electronics Corp.
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