AD ADP5033ACBZ-1-R7

Dual 3 MHz, 800 mA Buck
Regulators with Two 300 mA LDOs
ADP5033
The high switching frequency of the buck regulators enables
tiny multilayer external components and minimizes the board
space. When the MODE pin is set high, the buck regulators
operate in forced PWM mode. When the MODE pin is set low,
the buck regulators operate in QPXFSTBWFNPEFP4M
. When
UIFMPBEJTaround the nominal value and the load current falls
CFMPXBpredefined threshold, the regulator operates in 14.
improving the light load efficiency.
FEATURES
Main input voltage range: 2.3 V to 5.5 V
Two 800 mA buck regulators and two 300 mA LDOs
Tiny, 16-ball, 2 mm × 2 mm WLCSP package
Regulator accuracy: ±3%
Factory programmable VOUTx
3 MHz buck operation with forced PWM and auto PWM/PSM
modes
BUCK1/BUCK2: output voltage range from 0.8 V to 3.3 V
LDO1/LDO2: output voltage range from 0.8 V to 3.3V
LDO1/LDO2: low input supply voltage from 1.7 V to 5.5 V
LDO1/LDO2: high PSRR and low output noise
The two bucks operate out of phase to reduce the input capacitor
requirement and noise.
The low quiescent current, low dropout voltage, and wide input
voltage range of the ADP5033 LDO extend the battery life of
portable devices. The ADP5033 LDOs maintain power supply
rejection greater than 60 dB for frequencies as high as 10 kHz
while operating with a low headroom voltage.
APPLICATIONS
Power for processors, ASICS, FPGAs, and RF chipsets
Portable instrumentation and medical devices
Space constrained devices
The regulators in the ADP5033 are activated by the ENA and
ENB pins. The specific channels controlled by ENA and ENB
are set by factory programming. A high voltage level applied to
the enable pins activates the regulators. The default output
voltages are factory programmable and can be set to a wide
range of options.
GENERAL DESCRIPTION
The ADP5033 combines two high performance buck regulators
and two low dropout regulators (LDO) in a tiny, 16-ball, 2 mm ×
2 mm WLCSP to meet demanding performance and board
space requirements.
TYPICAL APPLICATION CIRCUIT
ADP5033
BUCK1
ENB
EN1
VIN2
MODE
SW2
L2 1µH
VOUT2 @
800mA
VOUT2
EN2
PGND2
EN3
VOUT3
LDO1
C6
10µF
C7
1µF
(ANALOG)
VIN4
C4
1µF
PWM
PSM/PWM
MODE
BUCK2
VIN3
C5
10µF
MODE
EN2
EN3
EN4
C2
4.7µF
C3
1µF
PGND1
EN4
VOUT4
LDO2
C8
1µF
(DIGITAL)
AGND
VOUT3 @
300mA
VOUT4 @
300mA
09788-001
ENA
1.7V TO 5.5V
VOUT1 @
800mA
VOUT1
C1
4.7µF
ON
OFF
L1 1µH
SW1
VIN1
ACTIV. AND
UVLO
2.3V TO 5.5V
Figure 1.
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2011 Analog Devices, Inc. All rights reserved.
ADP5033
TABLE OF CONTENTS
Features .............................................................................................. 1 Power Dissipation and Thermal Considerations ....................... 15 Applications....................................................................................... 1 Buck Regulator Power Dissipation .......................................... 15 General Description ......................................................................... 1 Junction Temperature ................................................................ 16 Typical Application Circuit ............................................................. 1 Theory of Operation ...................................................................... 17 Revision History ............................................................................... 2 Power Management Unit........................................................... 17 Specifications..................................................................................... 3 BUCK1 and BUCK2 .................................................................. 18 General Specifications ................................................................. 3 LDO1 and LDO2........................................................................ 19 BUCK1 and BUCK2 Specifications ........................................... 4 Applications Information .............................................................. 20 LDO1 and LDO2 Specifications................................................. 4 Buck External Component Selection....................................... 20 Input and Output Capacitor, Recommended Specifications.. 5 LDO Capacitor Selection .......................................................... 22 Absolute Maximum Ratings............................................................ 6 PCB Layout Guidelines.................................................................. 23 Thermal Resistance ...................................................................... 6 Typical Application Schematic ..................................................... 24 ESD Caution.................................................................................. 6 Outline Dimensions ....................................................................... 25 Pin Configuration and Function Descriptions............................. 7 Ordering Guide .......................................................................... 25 Typical Performance Characteristics ............................................. 8 REVISION HISTORY
5/11—Revision 0: Initial Version
Rev. 0 | Page 2 of 28
ADP5033
SPECIFICATIONS
GENERAL SPECIFICATIONS
VIN1 = VIN2 = VIN3 = VIN4 = 2.3 V to 5.5 V; VIN3 = VIN4 = 1.7 V to 5.5 V; TJ = −40°C to +125°C for minimum/maximum specifications, and
TA = 25°C for typical specifications, unless otherwise noted.
Table 1.
Parameter
INPUT VOLTAGE RANGE
THERMAL SHUTDOWN
Threshold
Hysteresis
START-UP TIME 1
BUCK1, LDO1, LDO2
BUCK2
ENA, ENB, MODE INPUTS
Input Logic High
Input Logic Low
Input Leakage Current
STANDBY CURRENT
All Channels Enabled
All Channels Disabled
VIN1 UNDERVOLTAGE LOCKOUT
High UVLO Input Voltage Rising
High UVLO Input Voltage Falling
Low UVLO Input Voltage Rising
Low UVLO Input Voltage Falling
1
Symbol
VIN1, VIN2
Test Conditions/Comments
TSSD
TSSD-HYS
TJ rising
Min
2.3
tSTART1
tSTART2
VIH
VIL
VI-LEAKAGE
ISTBY-NOSW
ISHUTDOWN
Typ
Max
5.5
150
20
°C
°C
250
300
μs
μs
1.1
No load, no buck switching
TJ = −40°C to +85°C
UVLOVIN1RISE
UVLOVIN1FALL
UVLOVIN1RISE
UVLOVIN1FALL
0.05
0.4
1
V
V
μA
108
0.3
175
1
μA
μA
3.9
V
V
V
V
3.1
2.275
1.95
Start-up time is defined as the time from VIN1 > UVLOVIN1RISE to VOUT1, VOUT2, VOUT3, and VOUT4 reaching 90% of their nominal levels.
Rev. 0 | Page 3 of 28
Unit
V
ADP5033
BUCK1 AND BUCK2 SPECIFICATIONS
VIN1 = VIN2 = 2.3 V to 5.5 V; TJ = −40°C to +125°C for minimum/maximum specifications, and TA = 25°C for typical specifications, unless
otherwise noted.1
Table 2.
Parameter
INPUT CHARACTERISTICS
Input Voltage Range
OUTPUT CHARACTERISTICS
Output Voltage Accuracy
Line Regulation
Load Regulation
PSM CURRENT THRESHOLD
PSM to PWM Operation
OPERATING SUPPLY CURRENT
BUCK1 Only
BUCK2 Only
BUCK1 and BUCK2
SW CHARACTERISTICS
SW On Resistance
Current Limit
ACTIVE PULL-DOWN
OSCILLATOR FREQUENCY
1
Symbol
Test Conditions/Comments
Min
VIN1, VIN2
PWM mode, ILOAD1 = ILOAD2 = 0 mA to 800 mA
2.3
VOUT1, VOUT2
VOUT1, VOUT2
IOUT1, IOUT2
PWM mode; VIN1 = VIN2 = 2.3 V to 5.5 V; ILOAD1 = ILOAD2 = 0 mA to 800 mA
−3
PWM mode
ILOAD = 0 mA to 800mA, PWM mode
Typ
IPSM
IIN
IIN
IIN
RPFET
RPFET
RNFET
RNFET
ILIMIT1, ILIMIT2
RPDWN-B
fSW
MODE = ground
ILOAD1 = 0 mA, device not switching, all other channels disabled.
ILOAD2 = 0 mA, device not switching, all other channels disabled.
ILOAD1 = ILOAD2 = 0 mA, device not switching, LDO channels disabled.
pFET at VIN1 = 5 V
pFET at VIN1 = 3.6 V
nFET at VIN1 = 5 V
nFET at VIN1 = 3.6 V
pFET switch peak current limit
1100
2.5
Unit
5.5
V
+3
%
−0.05
−0.1
%/V
%/A
100
mA
44
55
67
μA
μA
μA
145
180
110
125
1350
75
3.0
Channel disabled
Max
235
295
190
220
mΩ
mΩ
mΩ
mΩ
mA
Ω
MHz
3.5
All limits at temperature extremes are guaranteed via correlation using standard statistical quality control (SQC).
LDO1 AND LDO2 SPECIFICATIONS
VIN3 = (VOUT3 + 0.5 V) or 1.7 V (whichever is greater) to 5.5 V, VIN4 = (VOUT4 + 0.5 V) or 1.7 V (whichever is greater) to 5.5 V; CIN = COUT =
1 μF; TJ = −40°C to +125°C for minimum/maximum specifications, and TA = 25°C for typical specifications, unless otherwise noted.1
Table 3.
Parameter
INPUT VOLTAGE RANGE
OPERATING SUPPLY CURRENT
Bias Current per LDO2
Symbol
VIN3, VIN4
Test Conditions/Comments
IVIN3BIAS/IVIN4BIAS
Total System Input Current
LDO1 or LDO2 Only
LDO1 and LDO2 Only
OUTPUT CHARACTERISTICS
Output Voltage Accuracy
IIN
IOUT3 = IOUT4 = 0 μA
IOUT3 = IOUT4 = 10 mA
IOUT3 = IOUT4 = 300 mA
Includes all current into VIN1, VIN2, VIN3, and VIN4
IOUT3 = IOUT4 = 0 μA, all other channels disabled
IOUT3 = IOUT4 = 0 μA, buck channels disabled
Line Regulation
VOUT3, VOUT4
DROPOUT VOLTAGE4
∆VOUT3/∆VIN3,
∆VOUT4/∆VIN4
∆VOUT3/∆IOUT3,
∆VOUT4/∆IOUT4
VDROPOUT
CURRENT-LIMIT THRESHOLD5
ACTIVE PULL-DOWN
ILIMIT3, ILIMIT4
RPDWN-L
Load Regulation3
100 μA < IOUT3 < 300 mA, 100 μA < IOUT4 < 300 mA;
VIN3 = (VOUT3 + 0.5 V) to 5.5 V, VIN4 = (VOUT4 + 0.5 V) to 5.5 V
VIN3 = (VOUT3 + 0.5 V) to 5.5 V, VIN4 = (VOUT4 + 0.5 V) to
5.5 V, IOUT3 = IOUT4 = 1 mA
IOUT3 = IOUT4 = 1 mA to 300 mA
Min
1.7
Unit
V
10
60
165
30
100
245
μA
μA
μA
μA
μA
−3
+3
%
−0.03
+0.03
%/ V
0.001
0.003
%/mA
65
85
165
600
600
110
mV
mV
mV
mA
Ω
335
Rev. 0 | Page 4 of 28
Max
5.5
53
74
VOUT3 = VOUT4 = 3.3 V
VOUT3 = VOUT4 = 2.5 V
VOUT3 = VOUT4 = 1.8 V
Channel disabled
Typ
ADP5033
Parameter
POWER SUPPLY REJECTION
RATIO
Regulator LDO1
Symbol
PSRR
Regulator LDO2
Test Conditions/Comments
Min
10 kHz, VIN3 = 3.3 V, VOUT3 = 2.8 V, IOUT3 = 1 mA
100 kHz, VIN3 = 3.3 V, VOUT3 = 2.8 V, IOUT3 = 1 mA
1 MHz, VIN3 = 3.3 V, VOUT3 = 2.8 V, IOUT3 = 1 mA
10 kHz, VIN4 = 1.8 V, VOUT4 = 1.2 V, IOUT4 = 1 mA
100 kHz, VIN4 = 1.8 V, VOUT4 = 1.2 V, IOUT4 = 1 mA
1 MHz, VIN4 = 1.8 V, VOUT4 = 1.2 V, IOUT4 = 1 mA
Typ
60
62
63
54
57
64
Max
Unit
dB
dB
dB
dB
dB
dB
1
All limits at temperature extremes are guaranteed via correlation using standard statistical quality control (SQC).2
This is the input current into VIN3/VIN4, which is not delivered to the output load.
3
Based on an endpoint calculation using 1 mA and 100 mA loads.
4
Dropout voltage is defined as the input-to-output voltage differential when the input voltage is set to the nominal output voltage. This applies only to output voltages
above 1.7 V.
5
Current-limit threshold is defined as the current at which the output voltage drops to 90% of the specified typical value. For example, the current limit for a 3.0 V
output voltage is defined as the current that causes the output voltage to drop to 90% of 3.0 V, or 2.7 V.
2
INPUT AND OUTPUT CAPACITOR, RECOMMENDED SPECIFICATIONS
TA = −40°C to +125°C, unless otherwise specified.
Table 4.
Parameter
SUGGESTED INPUT AND OUTPUT CAPACITANCE
BUCK1, BUCK2 Input Capacitor
BUCK1, BUCK2 Output Capacitor
LDO1, LDO2 1 Input and Output Capacitors
CAPACITOR ESR
1
Symbol
Min
CMIN1, CMIN2
CMIN1, CMIN2
CMIN3, CMIN4
RESR
4.7
10
0.70
0.001
Typ
Max
Unit
40
40
μF
μF
μF
Ω
1
The minimum input and output capacitance should be greater than 0.70 μF over the full range of operating conditions. The full range of operating conditions in the
application must be considered during device selection to ensure that the minimum capacitance specification is met. X7R- and X5R-type capacitors are
recommended; Y5V and Z5U capacitors are not recommended for use with LDOs.
Rev. 0 | Page 5 of 28
ADP5033
ABSOLUTE MAXIMUM RATINGS
THERMAL RESISTANCE
Table 5.
Parameter
VIN1, VIN2, VIN3, VIN4, VOUT1, VOUT2,
VOUT3, VOUT4, ENA, MODE, ENB to
Ground
Storage Temperature Range
Operating Junction Temperature Range
Soldering Conditions
ESD Human Body Model
ESD Charged Device Model
ESD Machine Model
Rating
–0.3 V to +6 V
θJA and ΨJB are specified for the worst-case conditions, that is, a
device soldered in a circuit board for surface-mount packages.
–65°C to +150°C
–40°C to +125°C
JEDEC J-STD-020
±1500 V
±500 V
±100 V
Package Type
16-Ball, 0.5 mm Pitch WLCSP
Table 6. Thermal Resistance
ESD CAUTION
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
For detailed information on power dissipation, see the Power
Dissipation and Thermal Considerations section.
Rev. 0 | Page 6 of 28
θJA
57
ΨJB
14
Unit
°C/W
ADP5033
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
BALL A1
INDICATOR
2
1
3
4
VOUT3 VIN3
VIN4 VOUT4
AGND MODE
ENA
A
ENB
B
VIN1
VOUT1 VOUT2 VIN2
C
PGND1 SW1
SW2
PGND2
TOP VIEW
(BALL SIDE DOWN)
Not to Scale
09788-002
D
Figure 2. Pin Configuration—View from the Top of the Die
Table 7. Pin Function Descriptions
Pin No.
A1
A2
A3
A3
B1
B2
B3
B4
C1
C2
C3
C4
D1
D2
D3
D4
Mnemonic
VOUT3
VIN3
VIN4
VOUT4
AGND
MODE
ENA
ENB
VIN1
VOUT1
VOUT2
VIN2
PGND1
SW1
SW2
PGND2
Description
LDO1 Output Voltage and Sensing Input.
LDO1 Input Supply (1.7 V to 5.5 V, VIN4 ≤ VIN1 = VIN2).
LDO2 Input Supply (1.7 V to 5.5 V, VIN3 ≤ VIN1 = VIN2).
LDO2 Output Voltage and Sensing Input.
Analog Ground.
BUCK1/BUCK2 Operating Mode. MODE = high: forced PWM operation. MODE = low: auto PWM/PSM operation.
Regulator Enable Pin A, Active High. The regulators turned on with ENA are factory programmed.
Regulator Enable Pin B, Active High. The regulators turned on with ENB are factory programmed.
BUCK1 Input Supply (2.3 V to 5.5 V) and UVLO Detection. Connect VIN1 to VIN2.
BUCK1 Output Voltage Sensing Input.
BUCK2 Output Voltage Sensing Input.
BUCK2 Input Supply (2.3 V to 5.5 V). Connect VIN2 to VIN1.
Dedicated Power Ground for BUCK1.
BUCK1 Switching Node.
BUCK2 Switching Node.
Dedicated Power Ground for BUCK2.
Rev. 0 | Page 7 of 28
ADP5033
TYPICAL PERFORMANCE CHARACTERISTICS
VIN1= VIN2 = VIN3= VIN4 = 5.0 V, TA = 25°C, unless otherwise noted.
3.35
140
QUIESCENT CURRENT (µA)
120
VIN = 4.2V, +85°C
VIN = 4.2V, +25°C
VIN = 4.2V, –40°C
3.33
VOUTA (V)
100
80
60
3.31
3.29
40
3.27
2.8
3.3
3.8
4.3
4.8
3.25
09788-139
0
2.3
5.3
INPUT VOLTAGE (V)
Figure 3. System Quiescent Current vs. Input Voltage, VOUT1 = 3.3 V,
VOUT2 = 1.8 V, VOUT3 = 1.2 V, VOUT4 = 3.3 V, All Channels Unloaded
0
0.1
0.2
0.3
0.4
IOUT (A)
0.5
0.6
0.7
0.8
09788-058
20
Figure 6. BUCK1 Load Regulation Across Temperature, VOUT1 = 3.3 V,
Auto Mode
1.864
T
SW
VIN = 3.6V, +85°C
VIN = 3.6V, +25°C
VIN = 3.6V, –40°C
1.844
4
VOUTA (V)
VOUT
2
EN
1
1.824
1.804
IIN
1.784
M 40.0µs
A CH3
2.2V
T 11.20%
1.764
09788-021
CH2 50.0mA Ω
CH4 5.00V
CH1 2.00V
CH3 5.00V
0
0.1
0.2
0.3
0.4
0.5
IOUT (A)
0.799
T
0.8
VIN = 3.6V, +85°C
VIN = 3.6V, +25°C
VIN = 3.6V, –40°C
0.798
SW
0.797
VOUT
0.796
VOUTA (V)
4
EN
1
0.7
Figure 7. BUCK2 Load Regulation Across Temperature, VOUT2 = 1.8 V,
Auto Mode
Figure 4. Buck1 Startup, VOUT1 = 3.3 V, IOUT1 = 10 mA
2
0.6
09788-057
3
IIN
0.795
0.794
0.793
0.792
0.791
3
CH2 50.0mA Ω
CH4 5.00V
M 40.0µs
A CH3
2.2V
T 11.20%
0.789
09788-020
CH1 2.00V
CH3 5.00V
0
0.1
0.2
0.3
0.4
0.5
IOUT (A)
0.6
0.7
0.8
Figure 8. BUCK1 Load Regulation Across Input Voltage, VOUT1 = 3.3 V,
PWM Mode
Figure 5. BUCK2 Startup, VOUT2 = 1.8 V, IOUT2 = 5 mA
Rev. 0 | Page 8 of 28
09788-054
0.790
100
100
90
90
80
80
70
70
EFFICIENCY (%)
60
50
40
30
10
VIN = 5.5V
0.01
IOUT (A)
0.1
1
0
0.001
09788-038
0.001
0.1
1
Figure 12. BUCK2 Efficiency vs. Load Current, Across Input Voltage,
VOUT2 = 1.8 V, PWM Mode
90
90
80
80
70
70
EFFICIENCY (%)
100
60
50
40
60
50
40
30
VIN = 2.3V
VIN = 3.6V
VIN = 4.2V
VIN = 5.5V
20
20
VIN = 3.9V
10
10
VIN = 4.2V
VIN = 5.5V
0.1
1
IOUT (A)
0
0.001
09788-039
0.01
90
90
80
80
70
70
EFFICIENCY (%)
100
40
1
Figure 13. BUCK1 Efficiency vs. Load Current, Across Input Voltage,
VOUT1 = 0.8 V, Auto Mode
100
50
0.1
IOUT (A)
Figure 10. BUCK1 Efficiency vs. Load Current, Across Input Voltage,
VOUT1 = 3.3 V, PWM Mode
60
0.01
09788-034
30
60
50
40
30
30
VIN = 2.3V
VIN = 3.6V
VIN = 4.2V
VIN = 5.5V
10
0.01
0.1
IOUT (A)
VIN = 2.3V
VIN = 3.6V
VIN = 4.2V
VIN = 5.5V
20
10
1
0
0.001
09788-036
20
0
0.001
0.01
IOUT (A)
100
0
0.001
VIN = 2.4V
VIN = 3.6V
VIN = 4.5V
VIN = 5.5V
09788-035
VIN = 4.2V
Figure 9. BUCK1 Efficiency vs. Load Current, Across Input Voltage,
VOUT1 = 3.3 V, Auto Mode
EFFICIENCY (%)
40
20
VIN = 3.9V
10
EFFICIENCY (%)
50
30
20
0
0.0001
60
0.01
0.1
IOUT (A)
Figure 11. BUCK2 Efficiency vs. Load Current, Across Input Voltage,
VOUT2 = 1.8 V, Auto Mode
1
09788-065
EFFICIENCY (%)
ADP5033
Figure 14. BUCK1 Efficiency vs. Load Current, Across Input Voltage,
VOUT1 = 0.8 V, PWM Mode
Rev. 0 | Page 9 of 28
ADP5033
100
3.3
90
3.2
80
3.1
FREQUENCY (MHz)
EFFICIENCY (%)
70
60
50
40
30
3.0
2.9
2.8
2.7
20
0.1
1
IOUT (A)
2.5
0
0.2
0.4
0.6
IOUT (A)
0.8
1.0
1.2
09788-040
0.01
09788-062
0
0.001
TA = +25°C
TA = –40°C
TA = +85°C
2.6
+25°C
+85°C
–40°C
10
Figure 18. BUCK2 Switching Frequency vs. Output Current, Across
Temperature, VOUT2 = 1.8 V, PWM Mode
Figure 15. BUCK1 Efficiency vs. Load Current, Across Temperature,
VOUT1 = 3.3 V, Auto Mode
100
T
VOUT
90
80
1
EFFICIENCY (%)
70
ISW
60
2
50
40
SW
30
20
+85°C
+25°C
–40°C
0.01
0.1
4
1
IOUT (A)
CH1 50.0V
CH2 500mA Ω
CH4 2.00V
M 4.00µs
A CH2
240mA
T 28.40%
09788-025
0
0.001
09788-063
10
Figure 19. Typical Waveforms, VOUT1 = 3.3 V, IOUT1 = 30 mA, Auto Mode
Figure 16. BUCK2 Efficiency vs. Load Current, Across Temperature,
VOUT2 = 1.8 V, Auto Mode
100
T
90
VOUT
80
1
EFFICIENCY (%)
70
60
ISW
2
50
40
SW
30
20
+85°C
+25°C
–40°C
0.01
0.1
4
1
IOUT (A)
Figure 17. BUCK2 Efficiency vs. Load Current, Across Temperature,
CH1 50.0V
CH2 500mA Ω
CH4 2.00V
M 4.00µs
T 28.40%
A CH2
220mA
09788-024
0
0.001
09788-200
10
Figure 20. Typical Waveforms, VOUT2 = 1.8 V, IOUT2 = 30 mA, Auto Mode
Rev. 0 | Page 10 of 28
ADP5033
T
T
VOUT
1
VIN
ISW
VOUT
2
1
SW
SW
4
3
CH2 500mA Ω
CH4 2.00V
M 400ns
A CH2
220mA
T 28.40%
CH1 50.0mV
CH3 1.00V
09788-027
CH1 50mV
Figure 21. Typical Waveforms, VOUT1 = 3.3 V, IOUT1 = 30 mA, PWM Mode
CH4 2.00V
M 1.00ms
A CH3
4.80V
T 30.40%
09788-013
4
Figure 24. BUCK2 Response to Line Transient, VIN = 4.5 V to 5.0 V,
VOUT2 = 1.8 V, PWM Mode
T
T
SW
VOUT
1
4
ISW
VOUT
2
1
SW
IOUT
CH2 500mA Ω
CH4 2.00V
M 400ns
A CH2
220mA
T 28.40%
09788-026
CH1 50mV
CH1 50.0mV
Figure 22. Typical Waveforms, VOUT2 = 1.8 V, IOUT2 = 30 mA, PWM Mode
CH2 50.0mA Ω
CH4 5.00V
M 20.0µs A CH2
T 60.000µs
356mA
09788-016
2
4
Figure 25. BUCK1 Response to Load Transient, IOUT1 from 1 mA to 50 mA,
VOUT1 = 3.3 V, Auto Mode
T
T
SW
4
VIN
VOUT
VOUT
1
1
SW
IOUT
3
CH4 2.00V
M 1.00ms
T 30.40%
A CH3
4.80V
CH1 50.0mV
09788-012
CH1 50.0mV
CH3 1.00V
Figure 23. Buck1 Response to Line Transient, Input Voltage from 4.5 V to
5.0 V, VOUT1 = 3.3 V, PWM Mode
CH2 50.0mA Ω
CH4 5.00V
M 20.0µs A CH2
T 22.20%
379mA
09788-015
2
Figure 26. BUCK2 Response to Load Transient, IOUT2 from 1 mA to 50 mA,
VOUT2 = 1.8 V, Auto Mode
Rev. 0 | Page 11 of 28
ADP5033
T
T
SW
4
IIN
2
VOUT
1
VOUT
1
EN
IOUT
3
CH2 200mA Ω
CH4 5.00V
M 20.0µs A CH2
408mA
T 20.40%
CH2 50.0mA Ω
CH1 2.00V
CH3 5.00V
09788-017
CH1 50.0mV
Figure 27. BUCK1 Response to Load Transient, IOUT1 from 20 mA to 180 mA,
VOUT1 = 3.3 V, Auto Mode
M 40.0µs
A CH3
2.2V
T 11.20%
09788-022
2
Figure 30. LDO Startup, VOUT3 = 3.0 V, IOUT3 = 5 mA
2.820
T
SW
VIN = 3.3V
VIN = 4.5V
VIN = 5.0V
VIN = 5.5V
2.815
4
2.810
VOUTC (V)
2.805
VOUT
1
2.800
2.795
IOUT
2.790
2
CH2 200mA Ω
CH4 5.00V
M 20.0µs A CH2
88.0mA
T 19.20%
2.780
09788-018
CH1 100mV
0
0.05
0.10
0.15
IOUT (A)
0.20
0.25
0.30
09788-046
2.785
Figure 31. LDO Load Regulation Across Input Voltage, VOUT3 = 2.8 V
Figure 28. BUCK2 Response to Load Transient, IOUT2 from 20 mA to 180 mA,
VOUT2 = 1.8 V, Auto Mode
3.45
T
VOUT2
VIN = 4.2V, +85°C
VIN = 4.2V, +25°C
VIN = 4.2V, –40°C
3.40
2
SW1
VOUTD (V)
3.35
3
VOUT1
3.30
3.25
1
SW2
3.20
CH2 5.00V
CH4 5.00V
M 400ns
T 50.00%
A CH4
1.90V
3.15
09788-066
CH1 5.00V
CH3 5.00V
Figure 29. VOUT and SW Waveforms for BUCK1 and BUCK2 in PWM Mode
Showing Out-of-Phase Operation
0
0.05
0.10
0.15
IOUT (A)
0.20
0.25
0.30
09788-049
4
Figure 32. LDO Load Regulation Across Temperature, VIN3 = 3.3 V, VOUT3 = 2.8 V
Rev. 0 | Page 12 of 28
ADP5033
3.0
T
2.5
VIN
1.5
VOUT
2
1
1.0
IOUT = 300mA
IOUT = 150mA
IOUT = 100mA
IOUT = 10mA
IOUT = 1mA
IOUT = 100µA
0.5
3
CH1 20.0mV
CH3 1.00V
09788-045
0
2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 4.2 4.4 4.6 4.8 5.0 5.2 5.4
VIN (V)
Figure 33. LDO Line Regulation Across Output Load, VOUT3 = 2.8 V
M 100µs
T 28.40%
4.80V
Figure 36. LDO Response to Line Transient, Input Voltage from 4.5 V to 5.5 V,
VOUT3 = 2.8 V
50
60
5VIN
45
55
3.3VIN
40
GROUND CURRENT (µA)
A CH3
09788-014
VOUTC (V)
2.0
50
RMS NOISE (µV)
35
30
25
20
15
45
40
35
10
0
0.05
0.10
0.15
0.20
25
0.001
09788-136
0
0.25
LOAD CURRENT (A)
Figure 34. LDO Ground Current vs. Output Load, VIN3 = 3.3 V, VOUT3 = 2.8 V
0.01
1
ILOAD (mA)
10
100
Figure 37. LDO Output Noise vs. Load Current, Across Input Voltage,
VOUT3 = 2.8 V
65
T
5VIN
60
IOUT
3.3VIN
55
RMS NOISE (µV)
2
1
0.1
09788-047
30
5
VOUT
50
45
40
35
CH2 100mA Ω
M 40.0µs A CH2
T 19.20%
52.0mA
25
0.001
09788-019
CH1 100mV
Figure 35. LDO Response to Load Transient, IOUT3 from 1 mA to 80 mA,
VOUT3 = 2.8 V
Rev. 0 | Page 13 of 28
0.01
0.1
1
ILOAD (mA)
10
100
09788-048
30
Figure 38. LDO Output Noise vs. Load Current, Across Input Voltage,
VOUT3 = 3.0 V
ADP5033
0
–10
–20
–20
–40
–40
PSRR (dB)
PSRR (dB)
–30
0
100µA
1mA
10mA
50mA
100mA
150mA
–50
–60
100µA
1mA
10mA
50mA
100mA
150mA
–60
–80
–70
–80
–100
100
1k
10k
100k
FREQUENCY (Hz)
1M
10M
–120
10
09788-050
Figure 39. LDO PSRR Across Output Load, VIN3 = 3.3 V, VOUT3 = 2.8 V
10k
100k
FREQUENCY (Hz)
1M
10M
0
–10
–20
–20
–30
PSRR (dB)
–40
–60
–80
–100
100
1k
10k
100k
FREQUENCY (Hz)
100µA
1mA
10mA
50mA
100mA
150mA
–40
–50
–60
–70
100µA
1mA
10mA
50mA
100mA
150mA
–80
–90
1M
10M
09788-051
PSRR (dB)
1k
Figure 41. LDO PSRR Across Output Load, VIN3 = 5.0 V, VOUT3 = 2.8 V
0
–120
10
100
Figure 40. LDO PSRR Across Output Load, VIN3 = 3.3 V, VOUT3 = 3.0 V
–100
10
100
1k
10k
100k
FREQUENCY (Hz)
1M
10M
Figure 42. LDO PSRR Across Output Load, VIN3 = 5.0 V, VOUT3 = 3.0 V
Rev. 0 | Page 14 of 28
09788-052
–100
10
09788-053
–90
ADP5033
POWER DISSIPATION AND THERMAL CONSIDERATIONS
The ADP5033 is a highly efficient micropower management
unit (μPMU), and, in most cases, the power dissipated in the
device is not a concern. However, if the device operates at high
ambient temperatures and maximum loading condition, the
junction temperature can reach the maximum allowable
operating limit (125°C).
When the temperature exceeds 150°C, the ADP5033 turns off
all the regulators, allowing the device to cool down. When the
die temperature falls below 130°C, the ADP5033 resumes
normal operation.
This section provides guidelines to calculate the power dissipated in the device and ensure that the ADP5033 operates
below the maximum allowable junction temperature.
POUT
× 100%
PIN
The power loss of the buck regulator is approximated by
PLOSS = PDBUCK1 + PDBUCK2 + PL
(3)
where:
PDBUCK is the power dissipation on one of the ADP5033 buck
regulators.
PL is the inductor power losses.
The inductor losses are external to the device, and they do not
have any effect on the die temperature.
The inductor losses are estimated (without core losses) by
PL ≈ IOUT1(RMS)2 × DCRL
The efficiency for each regulator on the ADP5033 is given by
η=
BUCK REGULATOR POWER DISSIPATION
(1)
where:
DCRL is the inductor series resistance.
IOUT1(RMS) is the rms load current of the buck regulator.
I OUT 1( RMS) = I OUT1 × 1 +
where:
η is the efficiency.
PIN is the input power.
POUT is the output power.
(4)
r
12
(5)
where r is the inductor ripple current
r ≈ VOUT1 × (1 − D)/(IOUT1 × L × fSW)
Power loss is given by
PLOSS = PIN − POUT
(2a)
PLOSS = POUT (1− η)/η
(2b)
or
Power dissipation can be calculated in several ways. The most
intuitive and practical is to measure the power dissipated at the
input and all the outputs. Perform the measurements at the
worst-case conditions (voltages, currents, and temperature).
The difference between input and output power is dissipated in
the device and the inductor. Use Equation 4 to derive the power
lost in the inductor and, from this, use Equation 3 to calculate
the power dissipation in the ADP5033 buck converter.
A second method to estimate the power dissipation uses the
efficiency curves provided for the buck regulator, and the power
lost on each LDO can be calculated using Equation 12. When
the buck efficiency is known, use Equation 2b to derive the total
power lost in the buck regulator and inductor, use Equation 4 to
derive the power lost in the inductor, and then calculate the
power dissipation in the buck converter using Equation 3. Add
the power dissipated in the buck and in the two LDOs to find
the total dissipated power.
Note that the buck efficiency curves are typical values and may
not be provided for all possible combinations of VIN, VOUT, and
IOUT. To account for these variations, it is necessary to include a
safety margin when calculating the power dissipated in the buck.
(6)
where:
L is the inductance.
fSW is the switching frequency.
D is the duty cycle.
D = VOUT1/VIN1
(7)
ADP5033 buck regulator power dissipation, PDBUCK, includes the
power switch conductive losses, the switch losses, and the transition losses of each channel. There are other sources of loss, but
these are generally less significant at high output load currents,
where the thermal limit of the application is. Equation 8
captures the calculation that must be made to estimate the
power dissipation in the buck regulator.
PDBUCK = PCOND + PSW + PTRAN
(8)
The power switch conductive losses are due to the output current,
IOUT1, flowing through the P-MOSFET and the N-MOSFET
power switches that have internal resistance, RDSON-P and
RDSON-N. The amount of conductive power loss is found by
PCOND = [RDSON-P × D + RDSON-N × (1 − D)] × IOUT12
(9)
where RDSON-P is approximately 0.2 Ω, and RDSON-N is approximately 0.16 Ω at 125°C junction temperature and VIN1 = VIN2 =
3.6 V. At VIN1 = VIN2 = 2.3 V, these values change to 0.31 Ω and
0.21 Ω, respectively, and at VIN1 = VIN2 = 5.5 V, the values are
0.16 Ω and 0.14 Ω, respectively.
A third way to estimate the power dissipation is analytical and
involves modeling the losses in the buck circuit provided by
Equation 8 to Equation 11 and the losses in the LDO provided
by Equation 12.
Rev. 0 | Page 15 of 28
ADP5033
Switching losses are associated with the current drawn by the
driver to turn on and turn off the power devices at the switching
frequency. The amount of switching power loss is given by
PSW = (CGATE-P + CGATE-N) × VIN12 × fSW
(10)
where:
CGATE-P is the P-MOSFET gate capacitance.
CGATE-N is the N-MOSFET gate capacitance.
For the ADP5033, the total of (CGATE-P + CGATE-N) is approximately 150 pF.
(11)
where tRISE and tFALL are the rise time and the fall time of the
switching node, SW. For the ADP5033, the rise and fall times of
SW are in the order of 5 ns.
If the preceding equations and parameters are used for estimating the converter efficiency, it must be noted that the equations
do not describe all of the converter losses, and the parameter
values given are typical numbers. The converter performance
also depends on the choice of passive components and board
layout; therefore, a sufficient safety margin should be included
in the estimate.
LDO Regulator Power Dissipation
The power loss of a LDO regulator is given by
PDLDO = [(VIN − VOUT) × ILOAD] + (VIN × IGND)
where:
ILOAD is the load current of the LDO regulator.
VIN and VOUT are input and output voltages of the LDO,
respectively.
IGND is the ground current of the LDO regulator.
The total power dissipation in the ADP5033 simplifies to
PD = PDBUCK + PDLDO1 + PDLDO2
(12)
(13)
In cases where the board temperature TA is known, the thermal
resistance parameter, θJA, can be used to estimate the junction
temperature rise. TJ is calculated from TA and PD using the
formula
TJ = TA + (PD × θJA)
The transition losses occur because the P-channel power
MOSFET cannot be turned on or off instantaneously, and the
SW node takes some time to slew from near ground to near
VOUT1 (and from VOUT1 to ground). The amount of transition
loss is calculated by
PTRAN = VIN1 × IOUT1 × (tRISE + tFALL) × fSW
JUNCTION TEMPERATURE
(14)
The typical θJA value for the 16-ball, 0.5 mm pitch WLCSP is
57°C/W (see Table 6). A very important factor to consider is
that θJA is based on a 4-layer 4 in × 3 in, 2.5 oz copper, as per
JEDEC standard, and real applications may use different sizes
and layers. It is important to maximize the copper used to remove
the heat from the device. Copper exposed to air dissipates heat
better than copper used in the inner layers. The exposed pad
should be connected to the ground plane with several vias.
If the case temperature can be measured, the junction temperature is calculated by
TJ = TC + (PD × ΨJB)
(15)
where TC is the case temperature and ΨJB is the junction-toboard thermal resistance provided in Table 6.
When designing an application for a particular ambient
temperature range, calculate the expected ADP5033 power
dissipation (PD) due to the losses of all channels by using the
Equation 8 to Equation 13. From this power calculation, the
junction temperature, TJ, can be estimated using Equation 14.
The reliable operation of the converter and the two LDO regulators
can be achieved only if the estimated die junction temperature of
the ADP5033 (Equation 14) is less than 125°C. Reliability and
mean time between failures (MTBF) is highly affected by increasing the junction temperature. Additional information about
product reliability can be found in the ADI Reliability Handbook,
which can be found at www.analog.com/reliability_handbook.
Power dissipation due to the ground current is small, and it
can be ignored.
Rev. 0 | Page 16 of 28
ADP5033
THEORY OF OPERATION
VOUT1
GM ERROR
AMP
VDDA
ENBK1
VOUT2
75Ω
75Ω
ENBK2
ADP5033
GM ERROR
AMP
PWM
COMP
PWM
COMP
SOFT START
VIN1
VIN2
SOFT START
ILIMIT
ILIMIT
PSM
COMP
LOW
CURRENT
PSM
COMP
PWM/
PSM
CONTROL
BUCK1
PWM/
PSM
CONTROL
BUCK2
LOW
CURRENT
SW2
SW1
DRIVER
AND
ANTISHOOT
THROUGH
OSCILLATOR
DRIVER
AND
ANTISHOOT
THROUGH
SYSTEM
UNDERVOLTAGE
LOCKOUT
OPMODE
SEL
B
THERMAL
SHUTDOWN
PGND1
PGND2
MODE2
Y
ENLDO1
600Ω
A
MODE
ENBK1
ENABLE
AND MODE
CONTROL
ENB
LDO
UNDERVOLTAGE
LOCK OUT
R1
ENBK2
ENLDO1
ENLDO2
R3
LDO
CONTROL
VDDA
VDDA
600Ω
R2
VIN3
AGND VOUT3
VIN4
LDO
CONTROL
ENLDO1
R4
VOUT4
09788-003
ENA
LDO
UNDERVOLTAGE
LOCK OUT
Figure 43. Functional Block Diagram
POWER MANAGEMENT UNIT
The ADP5033 is a micropower management unit (μPMU)
combing two step-down (buck) dc-to-dc convertors and two
low dropout linear regulators (LDO). The high switching
frequency and tiny 16-ball WLCSP package allow for a small
power management solution.
To combine these high performance regulators into the μPMU,
there is a system controller allowing them to operate together.
The buck regulators can operate in forced PWM mode if the
MODE pin is at a logic high level. In forced PWM mode, the
buck switching frequency is always constant and does not
change with the load current. If the MODE pin is at logic low,
the switching regulators operate in auto PWM/PSM mode.
In this mode, the regulators operate at fixed PWM frequency
when the load current is above the power saving current threshold. When the load current falls below the power save current
threshold, the regulator in question enters PSM where the
switching occurs in bursts. The burst repetition is a
function of the current load and the output capacitor value.
This operating mode reduces the switching and quiescent current losses. The auto PWM/PSM mode transition is controlled
independently for each buck regulator. The two bucks operate
synchronized to each other.
When a regulator is turned on, the output voltage ramp is
controlled through a soft start circuit to avoid a large inrush
current due to the charging of the output capacitors.
Thermal Protection
In the event that the junction temperature rises above 150°C,
the thermal shutdown circuit turns off all the regulators. Extreme
junction temperatures can be the result of high current operation, poor circuit board design, or high ambient temperature.
A 20°C hysteresis is included so that when thermal shutdown
occurs, the regulators do not return to operation until the on-chip
temperature drops below 130°C. When coming out of thermal
shutdown, all regulators restart with soft start control.
Rev. 0 | Page 17 of 28
ADP5033
Undervoltage Lockout
BUCK1 AND BUCK2
To protect against battery discharge, undervoltage lockout (UVLO)
circuitry is integrated in the system. If the input voltage on VIN1
drops below a typical 2.15 V UVLO threshold, all channels shut
down. In the buck channels, both the power switch and the
synchronous rectifier turn off. When the voltage on VIN1 rises
above the UVLO threshold, the part is enabled once more.
The two bucks use a fixed frequency and high speed current
mode architecture. The bucks operate with an input voltage of
2.3 V to 5.5 V.
Control Scheme
In case of a thermal or UVLO event, the active pull-downs (if
factory enabled) are enabled to discharge the output capacitors
quickly. The pull-downs remain engaged until the input supply
voltage or thermal fault event is no longer present.
The bucks operate with a fixed frequency, current mode PWM
control architecture at medium to high loads for high efficiency
but shift to a PSM control scheme at light loads to lower the
regulation power losses. When operating in fixed frequency
PWM mode, the duty cycle of the integrated switches is adjusted
and regulates the output voltage. When operating in PSM at
light loads, the output voltage is controlled in a hysteretic
manner, with higher output voltage ripple. During part of this
time, the converter is able to stop switching and enters an idle
mode, which improves conversion efficiency.
Enable/Shutdown
PWM Mode
The ADP5033 has two enable pins (ENA and ENB). A high
level applied to the enable pins enables a certain selection of
regulators defined by factory programming. For example, the
ADP5033 can be factory programmed to enable BUCK1 and
LDO2 with ENA and BUCK2 and LDO1 with ENB. When both
enables are low, all regulators are turned off. When both enable
pins are high, all regulators are turned on. All possible regulator
combinations can be factory programmed to operate with the
ENA and ENB pins.
In PWM mode, the bucks operate at a fixed frequency of 3 MHz
set by an internal oscillator. At the start of each oscillator cycle,
the pFET switch is turned on, sending a positive voltage across
the inductor. Current in the inductor increases until the current
sense signal crosses the peak inductor current threshold that
turns off the pFET switch and turns on the nFET synchronous
rectifier. This sends a negative voltage across the inductor,
causing the inductor current to decrease. The synchronous
rectifier stays on for the rest of the cycle. The buck regulates the
output voltage by adjusting the peak inductor current threshold.
Alternatively, the user can select device models with a UVLO
set at a higher level, suitable for USB applications. For these
models, the device reaches the turn-off threshold when the
input supply drops to 3.65 V typical.
Figure 44 shows the regulator activation timings for the
ADP5033 when both enables are connected to VINx. Figure 44
also shows the active pull-down activation.
VIN1
VUVLO
VPOR
VOUT1
VOUT3
VOUT4
30µs (MIN)
VOUT2
30µs (MIN)
50µs (MIN)
50µs (MIN)
BUCK1, LDO1, LDO2
PULL-DOWNS
09788-148
BUCK2
PULL-DOWN
Figure 44. Regulators Sequencing on the ADP5033 (ENx = VINx)
Rev. 0 | Page 18 of 28
ADP5033
PSM
Current Limit
The bucks smoothly transition to PSM operation when the load
current decreases below the PSM current threshold. When
either of the bucks enters PSM, an offset is induced in the PWM
regulation level, which makes the output voltage rise. When the
output voltage reaches a level approximately 1.5% above the
PWM regulation level, PWM operation is turned off. At this
point, both power switches are off, and the buck enters an idle
mode. The output capacitor discharges until the output voltage
falls to the PWM regulation voltage, at which point the device
drives the inductor to make the output voltage rise again to the
upper threshold. This process is repeated while the load current
is below the PSM current threshold.
Each buck has protection circuitry to limit the amount of
positive current flowing through the pFET switch and the
amount of negative current flowing through the synchronous
rectifier. The positive current limit on the power switch limits
the amount of current that can flow from the input to the
output. The negative current limit prevents the inductor
current from reversing direction and flowing out of the load.
100% Duty Operation
The ADP5033 has a dedicated MODE pin controlling the PSM
and PWM operation. A high logic level applied to the MODE
pin forces both bucks to operate in PWM mode. A logic level
low sets the bucks to operate in auto PSM/PWM.
With a dropin input voltage or with an increase in load current,
the buck may reach a limit where, even with the pFET switch
on 100% of the time, the output voltage drops below the desired
output voltage. At this limit, the buck transitions to a mode
where the pFET switch stays on 100% of the time. When the
input conditions change again and the required duty cycle
falls, the buck immediately restarts PWM regulation without
allowing overshoot on the output voltage.
PSM Current Threshold
Active Pull-Downs
The PSM current threshold is set to100 mA. The bucks employ
a scheme that enables this current to remain accurately controlled, independent of input and output voltage levels. This
scheme also ensures that there is very little hysteresis between
the PSM current threshold for entry to and exit from the PSM.
The PSM current threshold is optimized for excellent efficiency
over all load currents.
All regulators have optional, factory programmable, active pulldown resistors discharging the respective output capacitors
when the regulators are disabled by the ENx pins or by a faulty
condition. The pull-down resistors are connected between
VOUTx and AGND. Active pull-downs are disabled when the
regulators are turned on. The typical value of the pull-down
resistor is 600 Ω for the LDOs and 75 Ω for the bucks. Figure 44
shows the activation timings for the active pull-down during
regulator activation and deactivation.
Oscillator/Phasing of Inductor Switching
The ADP5033 ensures that both bucks operate at the same
switching frequency when both bucks are in PWM mode.
LDO1 AND LDO2
Additionally, the ADP5033 ensures that when both bucks are in
PWM mode, they operate out of phase, whereby the Buck2
pFET starts conducting exactly half a clock period after the
Buck1 pFET starts conducting.
Short-Circuit Protection
The bucks include frequency foldback to prevent output current
runaway on a hard short. When the voltage at the feedback pin
falls below half the target output voltage, indicating the possibility of a hard short at the output, the switching frequency is
reduced to half the internal oscillator frequency. The reduction
in the switching frequency allows more time for the inductor to
discharge, preventing a runaway of output current.
Soft Start
The bucks have an internal soft start function that ramps the
output voltage in a controlled manner upon startup, thereby
limiting the inrush current. This prevents possible input voltage
drops when a battery or a high impedance power source is
connected to the input of the converter.
The ADP5033 contains two LDOs with low quiescent current
and two low dropout linear regulators and provides up to
300 mA of output current. Drawing a low 25 μA quiescent
current (typical) at no load makes the LDO ideal for batteryoperated portable equipment.
Each LDO operates with an input voltage of 1.7 V to 5.5 V. The
wide operating range makes these LDOs suitable for cascading
configurations where the LDO supply voltage is provided from
one of the buck regulators.
Each LDO also provides high power supply rejection ratio
(PSRR), low output noise, and excellent line and load transient
response with just a small 1 μF ceramic input and output
capacitor.
LDO1 is optimized to supply analog circuits because it offers
better noise performance compared to LDO2. LDO1 should be
used in applications where noise performance is critical.
Rev. 0 | Page 19 of 28
ADP5033
APPLICATIONS INFORMATION
BUCK EXTERNAL COMPONENT SELECTION
Output Capacitor
Trade-offs between performance parameters such as efficiency
and transient response can be made by varying the choice of
external components in the applications circuit, as shown in
Figure 1.
Higher output capacitor values reduce the output voltage ripple
and improve load transient response. When choosing this value,
it is also important to account for the loss of capacitance due to
output voltage dc bias.
Inductor
Ceramic capacitors are manufactured with a variety of dielectrics, each with a different behavior over temperature and
applied voltage. Capacitors must have a dielectric adequate
to ensure the minimum capacitance over the necessary
temperature range and dc bias conditions. X5R or X7R
dielectrics with a voltage rating of 6.3 V or 10 V are recommended for best performance. Y5V and Z5U dielectrics are
not recommended for use with any dc-to-dc converter because
of their poor temperature and dc bias characteristics.
The high switching frequency of the ADP5033 bucks allows for
the selection of small chip inductors. For best performance, use
inductor values between 0.7 μH and 3 μH. Suggested inductors
are shown in Table 8.
The peak-to-peak inductor current ripple is calculated using
the following equation:
VOUT × (VIN − VOUT )
VIN × f SW × L
The worst-case capacitance accounting for capacitor variation
over temperature, component tolerance, and voltage is calculated using the following equation:
where:
fSW is the switching frequency.
L is the inductor value.
CEFF = COUT × (1 − TEMPCO) × (1 − TOL)
The minimum dc current rating of the inductor must be greater
than the inductor peak current. The inductor peak current is
calculated using the following equation:
I PEAK = I LOAD( MAX ) +
I RIPPLE
2
Inductor conduction losses are caused by the flow of current
through the inductor, which has an associated internal dc
resistance (DCR). Larger sized inductors have smaller DCR,
which may decrease inductor conduction losses. Inductor core
losses are related to the magnetic permeability of the core material.
Because the bucks are high switching frequency dc-to-dc
converters, shielded ferrite core material is recommended for
its low core losses and low EMI.
where:
CEFF is the effective capacitance at the operating voltage.
TEMPCO is the worst-case capacitor temperature coefficient.
TOL is the worst-case component tolerance.
In this example, the worst-case temperature coefficient
(TEMPCO) over −40°C to +85°C is assumed to be 15% for an
X5R dielectric. The tolerance of the capacitor (TOL) is assumed
to be 10%, and COUT is 9.24 μF at 1.8 V, as shown in Figure 45.
Substituting these values in the equation yields
CEFF = 9.24 μF × (1 − 0.15) × (1 − 0.1) = 7.074 μF
To guarantee the performance of the bucks, it is imperative
that the effects of dc bias, temperature, and tolerances on the
behavior of the capacitors be evaluated for each application.
Table 8. Suggested 1.0 μH Inductors
Model
LQM2MPN1R0NG0B
LQM18FN1R0M00B
BRC1608T1R0M
EPL2014-102ML
GLFR1608T1R0M-LR
0603LS-102
MDT2520-CN
12
ISAT
(mA)
1400
150
520
900
230
400
1350
DCR
(mΩ)
85
26
180
59
80
81
85
10
CAPACITANCE (µF)
Vendor
Murata
Murata
Taiyo Yuden
Coilcraft®
TDK
Coilcraft
Toko
Dimensions
(mm)
2.0 × 1.6 × 0.9
1.6 × 0.8 × 0.8
1.6 × 0.8 × 0.8
2.0 × 2.0 × 1.4
1.6 × 0.8 × 0.8
1.8 × 1.69 × 1.1
2.5 × 2.0 × 1.2
8
6
4
2
0
0
1
2
3
4
5
DC BIAS VOLTAGE (V)
Figure 45. Typical Capacitor Performance
Rev. 0 | Page 20 of 28
6
09788-004
I RIPPLE =
ADP5033
The peak-to-peak output voltage ripple for the selected output
capacitor and inductor values is calculated using the following
equation:
VRIPPLE =
I RIPPLE
V IN
=
(2π × f SW ) × 2 × L × C OUT 8 × f SW × C OUT
Capacitors with lower equivalent series resistance (ESR) are
preferred to guarantee low output voltage ripple, as shown in
the following equation:
ESRCOUT ≤
VRIPPLE
I RIPPLE
The effective capacitance needed for stability, which includes
temperature and dc bias effects, is a minimum of 7 μF and a
maximum of 40 μF.
The buck regulators require 10 μF output capacitors to guarantee stability and response to rapid load variations and to
transition into and out of the PWM/PSM modes. In certain
applications, where one or both buck regulators power a
processor, the operating state is known because it is controlled
by software. In this condition, the processor can drive the
MODE pin according to the operating state; consequently, it is
possible to reduce the output capacitor from 10 μF to 4.7 μF
because the regulator does not expect a large load variation
when working in PSM mode (see Figure 47).
Table 9. Suggested 10 μF Capacitors
Vendor
Murata
Taiyo Yuden
TDK
Panasonic
Type
X5R
X5R
X5R
X5R
Model
GRM188R60J106
JMK107BJ475
C1608JB0J106K
ECJ1VB0J106M
Rev. 0 | Page 21 of 28
Case Size
0603
0603
0603
0603
Voltage Rating (V)
6.3
6.3
6.3
6.3
ADP5033
Input Capacitor
Higher value input capacitors help to reduce the input voltage
ripple and improve transient response. Maximum input
capacitor current is calculated using the following equation:
VOUT (VIN − VOUT )
VIN
To minimize supply noise, place the input capacitor as close
to the VINx pin of the buck as possible. As with the output
capacitor, a low ESR capacitor is recommended.
The effective capacitance needed for stability, which includes
temperature and dc bias effects, is a minimum of 3 μF and a
maximum of 10 μF. A list of suggested capacitors is shown in
Table 10.
Figure 46 depicts the capacitance vs. voltage bias characteristic
of a 0402 1 μF, 10 V, X5R capacitor. The voltage stability of a
capacitor is strongly influenced by the capacitor size and voltage
rating. In general, a capacitor in a larger package or higher voltage
rating exhibits better stability. The temperature variation of the
X5R dielectric is about ±15% over the −40°C to +85°C temperature range and is not a function of package or voltage rating.
1.2
Table 10. Suggested 4.7 μF Capacitors
Type
X5R
X5R
X5R
Model
GRM188R60J475ME19D
JMK107BJ475
ECJ-0EB0J475M
Voltage
Rating
(V)
6.3
6.3
6.3
LDO CAPACITOR SELECTION
Output Capacitor
The ADP5033 LDOs are designed for operation with small,
space-saving ceramic capacitors, but function with most
commonly used capacitors as long as care is taken with the ESR
value. The ESR of the output capacitor affects the stability of the
LDO control loop. A minimum of 0.70 μF capacitance with an
ESR of 1 Ω or less is recommended to ensure the stability of the
ADP5033. Transient response to changes in load current is also
affected by output capacitance. Using a larger value of output
capacitance improves the transient response of the ADP5033 to
large changes in load current.
Input Bypass Capacitor
Connecting a 1 μF capacitor from VIN3 and VIN4 to ground
reduces the circuit sensitivity to printed circuit board (PCB)
layout, especially when long input traces or a high source
impedance is encountered. If greater than 1 μF of output
capacitance is required, increase the input capacitor to match it.
Table 11. Suggested 1.0 μF Capacitors
Vendor
Murata
TDK
Panasonic
Taiyo Yuden
Type
X5R
X5R
X5R
X5R
Model
GRM155B30J105K
C1005JB0J105KT
ECJ0EB0J105K
LMK105BJ105MV-F
Case
Size
0402
0402
0402
0402
Voltage
Rating (V)
6.3
6.3
6.3
10.0
Input and Output Capacitor Properties
Use any good quality ceramic capacitors with the ADP5033 as
long as they meet the minimum capacitance and maximum ESR
requirements. Ceramic capacitors are manufactured with a
1.0
CAPACITANCE (µF)
Vendor
Murata
Taiyo Yuden
Panasonic
Case
Size
0402
0402
0402
0.8
0.6
0.4
0.2
0
0
1
2
3
4
DC BIAS VOLTAGE (V)
5
6
09788-006
I CIN ≥ I LOAD( MAX )
variety of dielectrics, each with a different behavior over
temperature and applied voltage. Capacitors must have a
dielectric adequate to ensure the minimum capacitance over the
necessary temperature range and dc bias conditions. X5R or
X7R dielectrics with a voltage rating of 6.3 V or 10 V are
recommended for best performance. Y5V and Z5U dielectrics
are not recommended for use with any LDO because of their
poor temperature and dc bias characteristics.
Figure 46. Capacitance vs. Voltage Characteristic
Use the following equation to determine the worst-case capacitance accounting for capacitor variation over temperature,
component tolerance, and voltage:
CEFF = CBIAS × (1 − TEMPCO) × (1 − TOL)
where:
CBIAS is the effective capacitance at the operating voltage.
TEMPCO is the worst-case capacitor temperature coefficient.
TOL is the worst-case component tolerance.
In this example, the worst-case temperature coefficient
(TEMPCO) over −40°C to +85°C is assumed to be 15% for an
X5R dielectric. The tolerance of the capacitor (TOL) is assumed
to be 10%, and CBIAS is 0.94 μF at 1.8 V, as shown in Figure 46.
Substituting these values into the following equation,
CEFF = 0.94 μF × (1 − 0.15) × (1 − 0.1) = 0.719 μF
Therefore, the capacitor chosen in this example meets the
minimum capacitance requirement of the LDO over
temperature and tolerance at the chosen output voltage.
To guarantee the performance of the ADP5033, it is imperative
that the effects of dc bias, temperature, and tolerances on the
behavior of the capacitors be evaluated for each application.
Rev. 0 | Page 22 of 28
ADP5033
PCB LAYOUT GUIDELINES
Poor layout can affect ADP5033 performance, causing electromagnetic interference (EMI) and electromagnetic compatibility
(EMC) problems, ground bounce, and voltage losses. Poor
layout can also affect regulation and stability. A good layout is
implemented using the following guidelines:
•
•
•
•
Place the inductor, input capacitor, and output capacitor
close to the IC using short tracks. These components carry
high switching frequencies, and large tracks act as antennas.
Route the output voltage path away from the inductor and
SW node to minimize noise and magnetic interference.
•
Rev. 0 | Page 23 of 28
Maximize the size of ground metal on the component side
to help with thermal dissipation.
Use a ground plane with several vias connecting to the
component side ground to further reduce noise interference on sensitive circuit nodes.
Connect VIN1 and VIN2 together close to the IC using
short tracks.
ADP5033
TYPICAL APPLICATION SCHEMATIC
ADP5033
L1 1µH
SW1
VIN1
VCORE
VCORE
VOUT1
C1
4.7µF
BUCK1
PROCESSOR
PGND1
C5
4.7µF
ALWAYS ON
ENA
VIN:
2.3V TO 5.5V
ACT
ENB
BK1
BK2
LD1
LD2
MODE
VIN2
SW2
C2
4.7µF
BUCK2
L2 1µH
FROM VCORE
(1.7V MIN)
VIN3
C3
1µF
VIN4
C4
1µF
LDO1
LDO2
VIO
VOUT2
PGND2
FROM VIO
(1.7V MIN)
GPIO
VIO
C6
4.7µF
VOUT3
C7
1µF
VOUT4
C8
1µF
ANALOG
SUBSYSTEM
VANA
VDIG
AGND
Figure 47. Processor System Power Management with PSM/PWM Control
Rev. 0 | Page 24 of 28
09788-152
ON
OFF
ADP5033
OUTLINE DIMENSIONS
2.12
2.08 SQ
2.04
0.660
0.602
0.544
0.022
REF
SEATING
PLANE
4
3
2
1
A
BALL 1
IDENTIFIER
0.380
0.352
0.324
C
0.04 NOM
COPLANARITY
D
0.50
REF
BOTTOM VIEW
(BALL SIDE UP)
0.280
0.250
0.220
013009-B
TOP VIEW
(BALL SIDE DOWN)
B
1.50
REF
0.330
0.310
0.290
Figure 48. 16-Ball Wafer Level Chip Scale Package [WLCSP]
Back-Coating Included
(CB-16-7)
Dimensions shown in millimeters
ORDERING GUIDE
Model 1
ADP5033ACBZ-1-R7
Temperature
Range
−40°C to +125°C
Output
Voltage (V) 2
VOUT1: 1.2 V
VOUT2: 3.3 V
VOUT3: 2.8 V
VOUT4: 1.8 V
Options
UVLO: 2.25 V
Pull-Downs on
All Channels
ENA
Controlled
Channels 3
BUCK2,
LDO1
ADP5033-1-EVALZ
Package
Description
16-Ball Wafer Level
Chip Scale
Package [WLCSP]
Evaluation Board
1
Z = RoHS Compliant Part.
2
For additional options, contact a local sales or distribution representative. Additional options available are
BUCK1 and BUCK2: 3.3 V, 3.0 V, 2.8 V, 2.5 V, 2.3 V, 2.0 V, 1.82 V, 1.8 V, 1.6 V, 1.5 V, 1.3 V, 1.2 V, 1.1 V, 1.0 V, 0.9 V, 0.8 V.
LDO1 and LDO2: 3.3 V, 3.0 V, 2.9 V, 2.8 V, 2.775 V, 2.5 V, 2.0 V, 1.875 V, 1.8 V, 1.75 V, 1.7 V, 1.65 V, 1.6 V, 1.55 V, 1.5 V, 1.2 V.
UVLO: 2.25 V or 3.9 V.
Active pull-down: Yes/No.
3
ENA activated channels (ENB controls the other channels).
Rev. 0 | Page 25 of 28
Package
Option
CB-16-7
Branding
Code
LHX
ADP5033
NOTES
Rev. 0 | Page 26 of 28
ADP5033
NOTES
Rev. 0 | Page 27 of 28
ADP5033
NOTES
©2011 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D09788-0-5/11(0)
Rev. 0 | Page 28 of 28