TI TPS51220A-Q1

TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Fixed Frequency, 99% Duty Cycle Peak Current Mode Notebook System Power Controller
Check for Samples: TPS51220A-Q1
FEATURES
1
•
•
•
•
2
•
•
•
•
•
•
•
Qualified for Automotive Applications
Input Voltage Range: 4.5 V to 32 V
Output Voltage Range: 1 V to 12 V
Selectable Light Load Operation
(Continuous / Auto Skip / Out-Of-Audio™ Skip)
Programmable Droop Compensation
Voltage Servo Adjustable Soft Start
200-kHz to 1-MHz Fixed-Frequency PWM
Selectable Current/ D-CAP™ Mode
Architecture
180° Phase Shift Between Channels
Resistor or Inductor DCR Current Sensing
Adaptive Zero Crossing Circuit
•
•
•
•
•
•
•
Powergood Output for Each Channel
OCL/OVP/UVP/UVLO Protections
(OVP Disable Option)
Thermal Shutdown (Non-Latch)
Output Discharge Function (Disable Option)
Latch-Up exceeds 100mA per JESD78- Class I
Integrated Boot Strap MOSFET Switch
QFN-32 (RTV) Package
APPLICATIONS
•
•
I/O Bus
Point of Load in LCD TV, MFP
DESCRIPTION
The TPS51220A-Q1 is a dual synchronous buck regulator controller with two LDOs. It is optimized for 5-V/3.3-V
system controller, enabling designers to cost effectively complete 2-cell to 4-cell notebook system power supply.
The TPS51220A-Q1 supports high efficiency, fast transient response, and 99% duty cycle operation. It supports
supply input voltage ranging from 4.5 V to 32 V, and output voltages from 1 V to 12 V. Two types of control
schemes can be chosen depending on the application. Peak current mode supports stability operation with lower
ESR capacitor and output accuracy. The D-CAP mode supports fast transient response. The high duty (99%)
operation and the wide input/output voltage range supports flexible design for small mobile PCs and a wide
variety of other applications. The fixed frequency can be adjusted from 200 kHz to 1 MHz by a resistor, and each
channel runs 180° out-of-phase. The TPS51220A-Q1 can also synchronize to the external clock, and the
interleaving ratio can be adjusted by its duty. The TPS51220A-Q1 is available in the 32-pin 5×5/4×4 QFN
package and is specified from –40°C to 105°C.
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
Out-Of-Audio, D-CAP, PowerPAD are trademarks of Texas Instruments.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2011, Texas Instruments Incorporated
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
TYPICAL APPLICATION CIRCUIT
VBAT
VBAT
Q21
C01
C14
PGND
C24
Q12
VO1
2
V5SW
3
RF
4
EN1
5
PGOOD1
6
SKIPSEL1
28
27
26
GN D
V BS T2
DRVH1
29
C21
Q22
D R VL 2
SW 1
V B ST 1
1
30
D RV L1
31
VR E G5
32
PGND
L2
PGND
GND
C11
PGND
C22
PGND
PGND
PGND
PGND
24
DRVH2
VIN
23
VBAT
VREG3
22
VREG3
3.3V/10mA
R01
C03
EN1
PGOOD1
SKIPSEL1
EN2
PGOOD2
20
PGOOD2
SKIPSEL2
19
10
11
12
13
18
CSN2
17
VF B 2
VR EF 2
9
CSP2
C OM P2
EN
GND
FU N C
CSN1
R24
C O MP 1
CSP1
8
VF B 1
7
C13
14
15
16
C23
VREG5
R21
R23
VO1
VO2
R11
R12
R22
GND
GND
2
GND
SKIPSEL2
PowerPAD
R14
EN
21
EN2
TPS51220A
(QFN32)
T RIP
GND
VO2
3.3V
25
SW 2
L1
VO1
5.0V
VREG5
5V/100mA
Q11
C12
C 02
R13
GND
GND
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These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
FUNCTIONAL BLOCK DIAGRAM
VIN
EN
V5SW
+
4.7V/ 4.5V
+
1.25V
+
+
VREG5
4.7V/ 4.5V
VREG3
GND
V5OK
+
4.2V/ 3.8V
Ready
GND
+
THOK
150/ 140
Deg-C
VREF2
1.25V
GND
GND
CLK2
OSC
RF
CLK1
GND
1V +5%/ 10%
+
PGOOD1
Delay
+
1V -30%
1V - 5%/ 10%
+
GND
CLK1
UVP
Ready
+
FUNC
Fault2
OVP
SDN2
1V +15%
Fault1
COMP1
Clamp (+)
Ramp
Comp
SDN1
+
Clamp (-)
CUR
+ PWM
VFB1
VREG5
D-CAP
1V
+
EN1
VFB-AMP
+
Enable/
Soft-start
Ramp
Comp
VBST1
+
Skip
Control
Logic
DRVH1
CS-AMP
CSN1
SW1
+
OCP
+
CSP1
VREF2
XCON
VREG5
100mV
TRIP
DRVL1
AZC
Discharge
Control
GND
GND
100mV
VREF2
N-OCP
+
GND
OOA
Ctrl
GND
SKIPSEL1
Channel-1 Switcher shown
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ABSOLUTE MAXIMUM RATINGS (1)
over operating free-air temperature range (unless otherwise noted)
TPS51220A-Q1
Input voltage range
(2)
VIN
–0.3 to 34
VBST1, VBST2
–0.3 to 39
VBST1, VBST2 (3)
–0.3 to 7
SW1, SW2
–7 to 34
CSP1, CSP2, CSN1, CSN2
–1 to 13.5
EN, EN1, EN2, VFB1, VFB2, TRIP, SKIPSEL1, SKIPSEL2, FUNC
–0.3 to 7
V
–1 to 7
V5SW
V5SW (to VREG5)
Output voltage range (2)
UNIT
(4)
–7 to 7
DRVH1, DRVH2
–7 to 39
V
DRVH1, DRVH2 (3)
–0.3 to 7
V
DRVL1, DRVL2, COMP1, COMP2, VREG5, RF, VREF2,
PGOOD1, PGOOD2
–0.3 to 7
V
–0.3 to 3.6
V
TJ
Junction temperature
150
°C
Tstg
Storage temperature
–55 to 150
°C
VREG3
(1)
(2)
(3)
(4)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only and functional operation of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
All voltage values are with respect to the network ground terminal unless otherwise noted.
Voltage values are with respect to the corresponding SW terminal.
When EN is high and V5SW is grounded, or voltage is applied to V5SW when EN is low.
DISSIPATION RATINGS (2 oz. Trace and Copper Pad with Solder)
PACKAGE
TA < 25°C
POWER RATING
(W)
DERATING FACTOR
ABOVE TA = 25°C
(mW/°C)
TA = 105°C
POWER RATING
(W)
32-pin RTV
1.7
17
0.34
RECOMMENDED OPERATING CONDITIONS
MIN
Supply voltage
VIN
V5SW
–0.8
6
VBST1, VBST2
–0.1
37
DRVH1, DRVH2
–4.
37
–0.1
6
-6
37
–4.
32
-6
32
CSP1, CSP2, CSN1, CSN2
–0.8
13
EN, EN1, EN2, VFB1, VFB2, TRIP, DRVL1, DRVL2, COMP1, COMP2,
VREG5, RF, VREF2, PGOOD1, PGOOD2, SKIPSEL1, SKIPSEL2,
FUNC
–0.1
6
VREG3
–0.1
3.5
–40
105
DRVH1, DRVH2 (negative overshoot -6 V for t < 20% duration of the
switching period)
SW1, SW2
TA
4
MAX
32
DRVH1, DRVH2 (wrt SW1, 2)
I/O voltage
TYP
4.5
SW1, SW2 (negative overshoot -6 V for t < 20% duration of the
switching period)
Operating free-air temperature
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UNIT
V
V
°C
Copyright © 2011, Texas Instruments Incorporated
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ORDERING INFORMATION
PACKAGE (1)
TA
QFN – RTV
-40°C to 105°C
(1)
Reel of 3000
ORDERABLE
PART
NUMBER
TOP-SIDE MARKING
TPS51220ATRTVRQ1
51220AT
For the most current package and ordering information, see the Package Option Addendum at the end of this document, or see the TI
website at www.ti.com.
ESD RATINGS TABLE
PARAMTER
VALUE
UNIT
Human Body Model (HBM)
2000
V
Charged-Device Model
500
V
Machine Model (MM)
100
V
ESD
ELECTRICAL CHARACTERISTICS
over operating free-air temperature range, EN = 3.3V, VIN = 12V, V5SW = 5V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
7
15
μA
80
120
μA
SUPPLY CURRENT
IVINSDN
VIN shutdown current
VIN shutdown current, TA = 25°C,
No Load, EN = 0V, V5SW = 0 V
IVINSTBY
VIN Standby Current
VIN standby current, TA = 25°C, No Load,
EN1 = EN2 = V5SW = 0 V
IVBATSTBY
VBAT Standby Current
Vbat standby current, TA = 25°C, No Load
SKIPSEL2 = 2V, EN2 = open, EN1 = V5SW = 0V (1)
IV5SW
V5SW Supply Current
V5SW current, TA = 25°C, No Load,
ENx = 5V, VFBx = 1.05 V
500
μA
TRIP = 5 V
0.8
mA
TRIP = 0 V
0.9
mA
VREF2 OUTPUT
VVREF2
VREF2 Output Voltage
I(VREF2) < ±10 μA, TA = 25°C
1.98
2.00
2.02
I(VREF2) < ±100 μA, 4.5V < VIN < 32 V
1.97
2.00
2.03
V
VREG3 OUTPUT
V5SW = 0 V, I(VREG3) = 0 mA, TA = 25°C
3.279
3.313
3.347
VVREG3
VREG3 Output Voltage
V5SW = 0 V, 0 mA < I(VREG3) < 10 mA,
5.5 V < VIN < 32 V
3.135
3.300
3.400
IVREG3
VREG3 Output Current
VREG3 = 3 V
10
15
20
V5SW = 0 V, I(VREG5) = 0 mA, TA = 25°C
4.99
5.04
5.09
V5SW = 0 V, 0 mA < I(VREG5) < 100 mA,
6 V < VIN < 32 V
4.90
5.03
5.15
V5SW = 0 V, 0 mA < I(VREG5) < 100 mA,
5.5 V < VIN < 32 V
4.50
5.03
5.15
V5SW = 0 V, VREG5 = 4.5 V
100
150
200
V5SW = 5 V, VREG5 = 4.5 V
200
300
400
Turning on
4.55
4.7
4.83
Hysteresis
0.15
0.20
0.25
V
mA
VREG5 OUTPUT
VVREG5
VREG5 Output Voltage
V
V
IVREG5
VREG5 Output Current
mA
VTHV5SW
Switchover Threshold
tdV5SW
Switchover Delay
Turning on
7.7
ms
RV5SW
5V SW On-Ressitance
I(VREG5) = 100 mA
0.5
Ω
V
OUTPUT
TA = 25°C, No Load
VVFB
VFB Regulation Voltage Tolerance
IVFB
VFB Input Current
VFBx = 1.05 V, COMPx = 1.8 V, TA = 25°C
RDISCHG
CSNx Discharge Resistance
ENx = 0 V, CSNx = 0.5 V, TA = 25°C
(1)
TA = –40°C to 105°C , No Load
0.9925
1.000
1.0075
0.990
1.000
1.010
–50
20
V
50
nA
40
Ω
Specified by design. Detail external condition follows application circuit of Figure 57.
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ELECTRICAL CHARACTERISTICS (continued)
over operating free-air temperature range, EN = 3.3V, VIN = 12V, V5SW = 5V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VOLTAGE TRANSCONDUCTANCE AMPLIFIER
gMv
Gain
VID
Differential Input Voltage Range
TA = 25°C
ICOMPSINK
COMP Maximum Sink Current
COMPx = 1.8 V
ICOMPSRC
COMP Maximum Source Current
COMPx = 1.8 V
VCOMP
VCOMPN
μS
500
–30
30
mV
TA = 0 to 105°C
27
33
μA
TA = –40 to
105°C
22
33
μA
–33
–43
μA
COMP Clamp Voltage
2.18
2.22
2.26
V
COMP Negative Clamp Voltage
1.73
1.77
1.81
V
CURRENT AMPLIFIER
GC
Gain
VIC
Common mode Input Voltage Range
VID
Differential Input Voltage Range
TRIP = 0V/2V, CSNx = 5V, TA = 25°C
(2)
TRIP = 3.3V/5V, CSNx = 5V, TA = 25°C
3.333
(2)
1.667
TA = 25°C
0
13
V
–75
75
mV
POWERGOOD
PG in from lower
92.5%
PG in from higher
95%
97.5%
VTHPG
PG threshold
102.5% 105% 107.5%
IPG
PG sink current
PGOOD = 0.5 V
5
IPG(LK)
PG leak current
PGOOD = 5 V
0
1
µA
tPGDLY
PGOOD delay
Delay for PG in
1.0
1.2
ms
tSSDYL
Soft Start Delay
Delay for Soft Start, ENx = Hi to SS-ramp starts
200
μs
tSS
Soft Start Time
Internal Soft Start
960
μs
PG hysteresis
5%
0.8
mA
SOFTSTART
FREQUENCY AND DUTY CONTROL
fSW
Switching Frequency
VTHRF
RF Threshold
fSYNC
Sync Input Frequency Range (2)
tON(min)
Minimum On Time
tOFF(min)
Minimum Off Time
RF = 330 kΩ
273
303
333
Lo to Hi
0.7
1.3
2
Hysteresis
0.2
200
V
1000
kHz
120
V(DRVH) = 90% to 10%, No Load, Auto-skip
160
250
ns
V(DRVH) = 10% to 90%, No Load
ns
290
400
ns
DRVH-off to DRVL-on
10
30
50
ns
DRVL-off to DRVH-on
30
40
70
ns
Dead time
VDTH
DRVH-off threshold
DRVH to GND
VDTL
DRVL-off threshold
DRVL to GND (2)
6
V
V(DRVH) = 90% to 10%, No Load, CCM/ OOA (2)
tD
(2)
kHz
(2)
1
V
1
V
Specified by design. Not production tested.
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ELECTRICAL CHARACTERISTICS (continued)
over operating free-air temperature range, EN = 3.3V, VIN = 12V, V5SW = 5V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
RTV package,
TA = 0 to 105°C
28
31
35
RSN
package
,
TA = 0 to 105°C
28
31
34
TA = –40 to
105°C
27
31
37
TA = 0 to 105°C
27
31
36
TA = –40 to
105°C
25
31
42
TA = 0 to 105°C
56
60
65
TA = –40 to
105°C
55
60
68
TA = 0 to 105°C
55
60
67
TA = –40 to
105°C
54
60
72
UNIT
CURRENT SENSE
TRIP=0V/ 2V, 2V<CSNx<12.6V
VOCL-ULV
Current limit threshold
(ultra-low voltage)
TRIP=0V/ 2V, 0.95V<CSNx<12.6V
TRIP=3.3V/ 5V, 2V<CSNx<12.6V
VOCL-LV
Current limit threshold
(low voltage)
TRIP=3.3V/ 5V,
0.95V<CSNx<12.6V
VZCAJ
Auto-Zero cross adjustable offset range
0.95V < CSNx < 12.6V, Auto-skip
VZC
Zero cross detection comparator Offset
0.95V < CSNx < 12.6V, OOA
VOCLN-ULV
Negative current limit threshold
(ultra-low voltage)
TRIP = 0V/2V, 0.95V < CSNx <
12.6V
VOCLN-LV
Negative current limit threshold
(low voltage)
TRIP = 3.3V/5V, 0.95V < CSNx <
12.6V
mV
Positive
5
Negative
–5
mV
mV
–5
0
4
TA = 0 to 105°C
–23
–31
–40
TA = –40 to
105°C
–22
–31
–44
TA = 0 to 105°C
–50
–60
–73
TA = –40 to
105°C
–49
–60
–77
mV
mV
OUTPUT DRIVERS
RDRVH
DRVH resistance
RDRVL
DRVL resistance
Source, V(VBST-DRVH) = 0.1 V
1.7
5
1
3
Source, V(VREG5-DRVL) = 0.1 V
1.3
4
Sink, V(DRVL-GND) = 0.1 V
0.7
2
Sink, V(DRVH-SW) = 0.1 V
Ω
Ω
UVP, OVP AND UVLO
VOVP
OVP Trip Threshold
tOVPDLY
OVP Prop Delay
VUVP
UVP Trip Threshold
tUVPDLY
UVP Delay
VUVREF2
VREF2 UVLO Threshold
VUVREG3
VREG3 UVLO Threshold
VUVREG5
VREG5 UVLO Threshold
OVP detect
110%
115%
120%
μs
1.5
UVP detect
65%
70%
73%
0.8
1
1.2
Wake up
1.7
1.8
1.9
V
Hysteresis
75
100
125
mV
3
3.1
3.2
0.10
0.15
0.20
Wake up
Hysteresis
Wake up
Hysteresis
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V
4.1
4.2
4.3
V
0.35
0.40
0.44
V
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ELECTRICAL CHARACTERISTICS (continued)
over operating free-air temperature range, EN = 3.3V, VIN = 12V, V5SW = 5V (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
INTERFACE AND LOGIC THRESHOLD
VEN
EN Threshold
IENLK
EN leak current
Wake up
0.8
1
1.2
Hysteresis
0.1
0.2
0.3
0.45
0.50
0.55
0.1
0.2
0.3
EN = 0 V, or EN = 3.3 V
-1
Wake up
VEN12
EN1/EN2 Threshold
VEN12SS
EN1/EN2 SS Start Threshold
SS-ramp start threshold at external soft start
VEN12SSEND
EN1/EN2 SS End Threshold
SS-End threshold at external soft start
IEN12
EN1/EN2 Source Current
VEN1/EN2 = 0V
Hysteresis
1
1
(3)
2
Continuous
VSKIPSEL
SKIPSEL1/SKIPSEL2 Setting Voltage
TRIP Setting Voltage
FUNC Setting Voltage
ITRIP
TRIP Input Current
ISKIPSEL
SKIPSEL Input Current
V
2.4
Auto Skip
1.9
2.1
OOA Skip (min 1/8 Fsw)
3.2
3.4
OOA Skip (min 1/16 Fsw)
3.8
μA
V
1.5
V(OCL-ULV), Discharge OFF
1.9
2.1
V(OCL-LV), Discharge OFF
3.2
3.4
V(OCL-LV), Discharge ON
3.8
Current mode, OVP enable
VFUNC
V
1.5
V(OCL-ULV), Discharge ON
VTRIP
μA
V
2
1.6
V
V
1.5
D-CAP mode, OVP disable
1.9
2.1
D-CAP mode, OVP enable
3.2
3.4
Current mode, OVP disable
3.8
TRIP = 0 V
–1
1
TRIP = 5 V
–1
1
SKIPSELx = 0 V
–0.5
0.5
SKIPSELx = 5 V
–0.5
0.5
V
μA
μA
BOOT STRAP SW
VFBST
Forward Voltage
VVREG5-VBST, IF = 10 mA, TA = 25°C
0.10
0.20
V
IBSTLK
VBST Leakage Current
VVBST = 37 V, VSW = 32 V
0.01
1.5
μA
Shutdown temperature (3)
150
THERMAL SHUTDOWN
TSDN
(3)
8
Thermal SDN Threshold
Hysteresis
(3)
10
°C
Specified by design. Not production tested.
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DEVICE INFORMATION
VBST2
SW2
25
GND
DRVL2
27
26
29
28
30
20
19
7
8
18
17
PGOOD2
SKIPSEL2
CSP2
CSN2
9
10
TPS51220A
VFB1
COMP1
FUNC
15
16
VREF2
TRIP
COMP2
VFB2
VFB1
COMP1
FUNC
CSN1
5
6
3
4
VREG3
EN2
15
16
18
17
SKIPSEL1
CSP1
DRVH2
VIN
EN
7
8
PGOOD2
SKIPSEL2
CSP2
CSN2
V5SW
RF
EN1
PGOOD1
24
23
22
21
1
2
VREF2
TRIP
COMP2
VFB2
20
19
VREG3
EN2
DRVH1
11
12
13
14
5
6
TPS51220A
9
10
CSN1
SW1
VBST1
DRVL1
VREG5
DRVH2
VIN
3
4
SKIPSEL1
CSP1
32
31
VBST2
SW2
25
GND
DRVL2
27
26
30
24
23
22
21
11
12
13
14
V5SW
RF
EN1
PGOOD1
RTV PACKAGE
(TOP VIEW)
1
2
EN
DRVH1
29
28
32
31
SW1
VBST1
DRVL1
VREG5
RSN PACKAGE
(TOP VIEW)
PIN FUNCTIONS
PIN
NAME
NO.
DRVH1
1
DRVH2
24
SW2
25
SW1
32
VREG3
22
EN1
4
EN2
21
PGOOD1
5
PGOOD2
20
SKIPSEL1
6
SKIPSEL2
19
CSP1
7
CSP2
18
CSN1
8
CSN2
17
VFB1
9
VFB2
16
COMP1
10
COMP2
15
RF
3
I/O
DESCRIPTION
O
High-side MOSFET gate driver outputs. Source 1.7 Ω, sink 1.0 Ω, SW-node referenced floating driver. Drive
voltage corresponds to VBST to SW voltage.
I/O
High-side MOSFET gate driver returns.
O
Always alive 3.3 V, 10 mA low dropout linear regulator output. Bypass to (signal) GND with more than 1-μF
ceramic capacitance. Runs from VIN supply or from VREG5 when it is switched over to V5SW input.
I
Channel 1 and channel 2 SMPS Enable Pins. When turning on, apply greater than 0.55 V and less than 6 V,
or leave floating. Connect to GND to disable. Adjustable soft-start capacitance to be attached here.
O
Powergood window comparator outputs for channel 1 and channel 2. The recommended applied voltage
should be less than 6 V, and the recommended pull-up resistance value is from 100 kΩ to 1 MΩ.
Skip mode selection pin.
I
GND: Continuous conduction mode
VREF2: Auto Skip
VREG3: OOA Auto Skip, maximum 7 skips (suitable for fsw < 400kHz)
VREG5: OOA Auto Skip, maximum 15 skips (suitable for equal to or greater than 400kHz)
I/O
Current sense comparator inputs (+). An RC network with high quality X5R or X7R ceramic capacitor should
be used to extract voltage drop across DCR. 0.1-μF is a good value to start the design. See the current
sensing scheme section for more details.
I
Current sense comparator inputs (–). See the current sensing scheme section. Used as power supply for the
current sense circuit for 5V or higher output voltage setting. Also, used for output discharge terminal.
I
SMPS voltage feedback Inputs. Connect the feedback resistors divider, and should be referred to (signal)
GND.
I
Loop compensation pin for current mode (error amplifier output). Connect R (and C if required) from this pin
to VREF2 for proper loop compensation with current mode operation. Ramp compensation adjustable pin for
D-CAP mode, connect R from this pin to VREF2. 10 kΩ is a good value to start the design. 6 kΩ to 20 kΩ
can be chosen. See the D-CAP MODE section for more details.
I/O
Frequency setting pin. Connect a frequency setting resistor to (signal) GND. Connect to an external clock for
synchronization.
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PIN FUNCTIONS (continued)
PIN
NAME
NO.
I/O
DESCRIPTION
Control architecture and OVP functions selection pin.
FUNC
11
I
VREF2
13
O
GND: Current mode, OVP enable
VREF2: D-CAP mode, OVP disable
VREG3: D-CAP mode, OVP enable
VREG5: Current mode, OVP disable
2-V reference output. Bypass to (signal) GND with 0.22-μF of ceramic capacitance.
Overcurrent trip level and discharge mode selection pin.
GND: V(OCL-ULV) , discharge on
VREF2: V(OCL-ULV), discharge off
VREG3: V(OCL-LV), discharge off
VREG5: V(OCL-LV), discharge on
TRIP
14
I
EN
12
I
VREF2 and VREG5 linear regulators enable pin. When turning on, apply greater than 1.2 V and less than 6
V. Connect to GND to disable.
VBST1
31
I
Supply inputs for high-side N-channel FET driver (boot strap terminal). Connect a capacitor (0.1-μF or
greater is recommended) from this pin to respective SW terminal. Additional SB diode from VREG5 to this
pin is an optional.
O
Low-side MOSFET gate driver outputs. Source 1.3 Ω, sink 0.7 Ω, and GND referenced driver.
I
VREG5 switchover power supply input pin. When EN1 is high, PGOOD1 indicates GOOD and V5SW
voltage is higher than 4.83 V, switch-over function is enabled.
Note: When switch-over is enabled, VREG5 output voltage is approximately equal to the V5SW input
voltage.
O
5-V, 100-mA low dropout linear regulator output. Bypass to (power) GND using a 10-μF ceramic capacitor.
Runs from VIN supply. Internally connected to VBST and DRVL. Shuts off with EN. Switches over to V5SW
when 4.83 V or above is provided.
Note: When switch-over (see above V5SW) is enabled, VREG5 output voltage is approximately equal to
V5SW input voltage.
VBST2
26
DRVL1
30
DRVL2
27
V5SW
2
VREG5
29
VIN
23
I
Supply input for 5-V and 3.3-V linear regulator. Typically connected to VBAT.
GND
28
–
Ground
10
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TYPICAL CHARACTERISTICS
INPUT VOLTAGE SHUTDOWN CURRENT
vs
INPUT VOLTAGE
INPUT VOLTAGE SHUTDOWN CURRENT
vs
JUNCTION TEMPERATURE
15
15
VI = 12 V
IVINSDN -– Shutdown Current – mA
IVINSDN -– Shutdown Current – mA
TA = 25°C
12
9
6
3
10
15
20
25
9
6
3
0
-50
0
5
12
30
0
VI – Input Voltage – V
Figure 1.
Figure 2.
INPUT VOLTAGE STANDBY CURRENT
vs
JUNCTION TEMPERATURE
INPUT VOLTAGE STANDBY CURRENT
vs
INPUT VOLTAGE
150
150
TA = 25°C
IVINSTBY – Standby Current – mA
VI = 12 V
IVINSTBY – Standby Current – mA
100
TJ – Junction Temperature – °C
150
120
90
60
30
0
-50
50
120
90
60
30
0
0
50
100
150
5
TJ – Junction Temperature – °C
Figure 3.
10
15
20
25
30
VI – Input Voltage – V
Figure 4.
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TYPICAL CHARACTERISTICS (continued)
NO LOAD BATTERY CURRENT
vs
INPUT VOLTAGE
NO LOAD BATTERY CURRENT
vs
INPUT VOLTAGE
1.0
1.0
EN = on
EN1 = off
EN2 = on
0.8
EN = on
EN1 = on
EN2 = on
0.9
IVBAT – Battery Current – mA
IVBAT – Battery Current – mA
0.9
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0
0
5
10
15
20
25
5
10
20
25
VI – Input Voltage – V
VI – Input Voltage – V
Figure 5.
Figure 6.
BATTERY CURRENT
vs
INPUT VOLTAGE
VREF2 OUTPUT VOLTAGE
vs
OUTPUT CURRENT
1.0
2.02
EN = on
EN1 = on
EN2 = off
0.8
VI = 12 V
VVREF2 – VREF2 Output Voltage – V
0.9
IVBAT – Battery Current – mA
15
2.01
0.7
0.6
0.5
2.00
0.4
0.3
1.99
0.2
0.1
0
5
10
15
20
25
1.98
–100
VI – Input Voltage – V
Figure 7.
12
–50
0
50
100
IVREF2 – VREF2 Output Current – mA
Figure 8.
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TYPICAL CHARACTERISTICS (continued)
VREG3 OUTPUT VOLTAGE
vs
OUTPUT CURRENT
VREG5 OUTPUT VOLTAGE
vs
OUTPUT CURRENT
3.40
VVREG5 – 5-V Linear Regulator Output Voltage – V
VVREG3 – 3.3-V Linear Regulator Output Voltage – V
5.10
VI = 12 V
3.35
VI = 12 V
5.05
3.30
5.00
3.25
4.95
3.20
4.90
0
2
4
6
8
10
0
IREG3 – 3-V Linear Regulator Output Current – mA
40
60
80
100
IREG5 – 5-V Linear Regulator Output Current – mA
Figure 9.
Figure 10.
SWITCHING FREQUENCY
vs
JUNCTION TEMPERATURE
FORWARD VOLTAGE OF BOOST SW
vs
JUNCTION TEMPERATURE
330
VFBST – Forward Voltage Boost Voltage – V
0.25
RRF = 330 kW
fSW – Switching Frequency – kHz
20
320
0.20
310
0.15
300
0.10
290
0.05
280
270
-50
0
50
100
150
0
-50
TJ – Junction Temperature – °C
Figure 11.
0
50
100
150
TJ – Junction Temperature – °C
Figure 12.
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TYPICAL CHARACTERISTICS (continued)
OVP/UVP THRESHOLD VOLTAGE
vs
JUNCTION TEMPERATURE
VBST LEAKAGE CURRENT
vs
JUNCTION TEMPERATURE
150
1.5
IBSTLK – VBST Leakage Current – mA
Voltage Protection Threshold – %
OVP
UVP
130
110
90
70
50
-50
0
50
100
1.2
0.9
0.6
0.3
0
-50
150
TJ – Junction Temperature – °C
Figure 14.
CURRENT LIMIT THRESHOLD
vs
JUNCTION TEMPERATURE
CURRENT LIMIT THRESHOLD
vs
JUNCTION TEMPERATURE
150
66
VCSN (V)
VOCL-LV – Current Limit Threshold – mV
VOCL-ULV – Current Limit Threshold – mV
100
Figure 13.
1
5
12
35
33
31
29
27
0
50
100
150
VCSN (V)
1
5
12
64
62
60
58
56
54
-50
TJ – Junction Temperature – °C
Figure 15.
14
50
TJ – Junction Temperature – °C
37
25
-50
0
0
50
100
150
TJ – Junction Temperature – °C
Figure 16.
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TYPICAL CHARACTERISTICS (continued)
5-V OUTPUT VOLTAGE
vs
INPUT VOLTAGE
3.3-V OUTPUT VOLTAGE
vs
INPUT VOLTAGE
3.40
5.2
Auto-Skip Mode
fSW = 330 kHz
Auto-Skip Mode
fSW = 330 kHz
5.0
VO2 – 3.3-V Output Voltage – V
VO1 – 5-V Output Voltage – V
5.1
3.35
4.9
4.8
3.30
4.7
4.6
4.5
3.25
IO (A)
4.4
0
4
8
4.3
4.2
4.5
5.0
5.5
6.5
6.0
0
4
8
3.20
4.5
7.0
IO (A)
5.0
5.5
6.5
6.0
VI – Input Voltage – V
VI – Input Voltage – V
Figure 17.
Figure 18.
5-V EFFICIENCY
vs
OUTPUT CURRENT
5-V EFFICIENCY
vs
OUTPUT CURRENT
100
100
Auto-Skip
VI = 8 V
80
90
h – Efficiency – %
h – Efficiency – %
VI = 12 V
60
7.0
CCM
OOA
40
Current Mode
VI = 12 V
RGV = 18 kW
20
0
0.001
0.01
0.1
1
80
70
Auto-Skip
Current Mode
RGV = 18 kW
60
10
VI = 20 V
50
0.001
IO1 – 5-V Output Current – A
Figure 19.
0.01
0.1
1
10
IO1 – 5-V Output Current – A
Figure 20.
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TYPICAL CHARACTERISTICS (continued)
3.3-V EFFICIENCY
vs
OUTPUT CURRENT
3.3-V EFFICIENCY
vs
OUTPUT CURRENT
100
100
VI = 8 V
Auto-Skip
90
VI = 12 V
60
h – Efficiency – %
h – Efficiency – %
80
CCM
OOA
40
VI = 12 V
Current Mode
RGV = 12 kW
5.0-V SMPS: ON
20
0
0.001
0.01
0.1
1
80
70
60
40
0.001
5-V SWITCHING FREQUENCY
vs
OUTPUT CURRENT
3.3-V SWITCHING FREQUENCY
vs
OUTPUT CURRENT
10
400
CCM
350
fSW – Switching Frequency – kHz
350
fSW – Switching Frequency – kHz
1
Figure 22.
CCM
300
250
200
150
OOA
300
250
200
150
100
OOA
50
50
Auto-Skip
0.01
0.1
1
10
0
0.001
IO1 – 5-V Output Current – A
Figure 23.
16
0.1
Figure 21.
400
0
0.001
0.01
IO2 – 3.3-V Output Current – A
IO2 – 3.3-V Output Current – A
100
Auto-Skip
Current Mode
RGV = 12 kW
5.0-V SMPS: ON
50
10
VI = 20 V
Auto-Skip
0.01
0.1
1
10
IO2 – 3.3-V Output Current – A
Figure 24.
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TYPICAL CHARACTERISTICS (continued)
5-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
3.3-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
5.10
3.40
5.08
3.38
5.06
VO2 – 3.3-V Output Voltage – V
VO1 – 5.0-V Output Voltage – V
Auto-Skip
and
OOA
3.36
Auto-Skip
5.04
3.34
5.02
3.32
5.00
3.30
OOA
4.98
CCM
3.28
CCM
4.96
3.26
4.94
3.24
VI = 12 V
Current Mode
RGV = 18 kW
4.92
VI = 12 V
Current Mode
RGV = 12 kW
3.22
4.90
3.20
0
1
2
4
3
6
5
7
8
0
1
3
4
5
6
7
8
IO2 – 3.3-V Output Current – A
IO1 – 5-V Output Current – A
Figure 25.
Figure 26.
5-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
3.3-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
5.10
3.40
5.08
3.38
5.06
Auto-Skip
and
OOA
5.04
Auto-Skip
and
OOA
3.36
VO2 – 3.3-V Output Voltage – V
VO1 – 5.0-V Output Voltage – V
2
3.34
5.02
3.32
5.00
3.30
4.98
CCM
3.28
4.96
VI = 12 V
Current Mode
(Non-droop)
RGV = 10 kW
C = 1.8 nF
4.94
4.92
3.26
1
2
3
4
5
6
7
VI = 12 V
Current Mode
(Non-droop)
RGV = 9.1 kW
C = 1.8 nF
3.24
3.22
4.90
0
CCM
8
3.20
0
1
IO1 – 5-V Output Current – A
Figure 27.
2
3
4
5
6
7
8
IO2 – 3.3-V Output Current – A
Figure 28.
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TYPICAL CHARACTERISTICS (continued)
5-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
3.3-V OUTPUT VOLTAGE
vs
OUTPUT CURRENT
5.10
3.40
5.08
3.38
Auto-Skip
3.36
VO2 – 3.3-V Output Voltage – V
VO1 – 5.0-V Output Voltage – V
5.06
Auto-Skip
and
OOA
3.34
5.04
3.32
5.02
5.00
3.30
OOA
4.98
3.28
CCM
CCM
3.26
4.96
4.94
3.24
VI = 12 V
D-CAP Mode
RGV = 10 kW
4.92
VI = 12 V
D-CAP Mode
RGV = 10 kW
3.22
3.20
4.90
1
2
3
4
5
6
7
0
8
1
2
3
6
7
Figure 29.
Figure 30.
5.0-V BODE-PLOT – GAIN AND PHASE
vs
FREQUENCY
3.3-V BODE-PLOT – GAIN AND PHASE
vs
FREQUENCY
80
180
80
8
180
Phase
Phase
135
60
135
40
90
40
90
20
45
20
45
0
Gain
0
–20
–40
–60
–80
100
VO= 5.0 V
VI = 12 V
IO = 8 A
1k
100 k
–20
–90
–40
–180
1M
Gain
0
45
–135
10 k
Gain – dB
60
Phase – °
Gain – dB
5
IO2 – 3.3-V Output Current – A
IO1 – 5-V Output Current – A
–60
0
45
–90
VO= 3.3 V
VI = 12 V
IO = 8 A
–80
100
1k
–135
10 k
100 k
–180
1M
f – Frequency – Hz
f – Frequency – Hz
Figure 31.
18
4
Phase – °
0
Figure 32.
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TYPICAL CHARACTERISTICS (continued)
5.0-V SWITCH-OVER WAVEFORMS
VREG5 (100 mV/div)
VO1 (100 mV/div)
2 ms/div
Figure 33.
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TYPICAL CHARACTERISTICS
5.0-V START-UP WAVEFORMS
3.3-V START-UP WAVEFORMS
EN2 (5V/div)
EN1 (5V/div)
Vout1 (2V/div)
Vout2 (2V/div)
PGOOD2 (5V/div)
1msec/div
PGOOD1 (5V/div)
1msec/div
Figure 34.
Figure 35.
5.0-V SOFT-STOP WAVEFORMS
3.3-V SOFT-STOP WAVEFORMS
EN1 (5V/div)
EN2 (5V/div)
Vout1 (2V/div)
Vout2 (2V/div)
PGOOD2 (5V/div)
PGOOD1 (5V/div)
10msec/div
1msec/div
1msec/div
10msec/div
Figure 36.
20
Figure 37.
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TYPICAL CHARACTERISTICS (continued)
5.0-V LOAD TRANSIENT RESPONSE
3.3-V LOAD TRANSIENT RESPONSE
VI =12V, Auto-skip
VI=12V, Auto-skip
VO1 (100mV/div)
VO2 (100mV/div)
SW1 (10V/div)
IO1 (5A/div)
100
100 mms/div
s/div
SW2 (10V/div)
IO2 (5A/div)
100
100 mms/div
s/div
Figure 38.
Figure 39.
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DETAILED DESCRIPTION
ENABLE AND SOFT START
When EN is Low, the TPS51220A-Q1 is in the shutdown state. Only the 3.3-V LDO stays alive, and consumes 7
μA (typically). When EN becomes High, the TPS51220A-Q1 is in the standby state. The 2-V reference and the
5-V LDO become enabled, and consume about 80 μA with no load condition, and are ready to turn on SMPS
channels. Each SMPS channel is turned on when ENx becomes High. After ENx is set to high, the
TPS51220A-Q1 begins the softstart sequence, and ramps up the output voltage from zero to the target voltage in
0.96 ms. However, if a slower soft-start is required, an external capacitor can be tied from the ENx pin to GND.
In this case, the TPS51220A-Q1 charges the external capacitor with the integrated 2-μA current source. An
approximate external soft-start time would be tEX-SS = CEX / IEN12, which means the time from ENx = 1 V to ENx =
2 V. The recommend capacitance is more than 2.2 nF.
1) Internal
Soft-start
EN1
Vout1
200ms
960ms
EN1<2V
EN1>1V
2) External
Soft-start
EN1
External
Soft-start
time
Vout1
Figure 40. Enable and Soft-start Timing
Table 1. Enable Logic States
EN
EN1
EN2
VREG3
VREF2
VREG5
CH1
CH2
GND
Don’t Care
Don’t Care
ON
Off
Off
Off
Off
Hi
Lo
Lo
ON
ON
ON
Off
Off
Hi
Hi
Lo
ON
ON
ON
ON
Off
Hi
Lo
Hi
ON
ON
ON
Off
ON
Hi
Hi
Hi
ON
ON
ON
ON
ON
PRE-BIASED START-UP
The TPS51220A-Q1 supports a pre-biased start up by preventing negative inductor current during soft-start when
the output capacitor holds some charge. The initial DRVH signal waits until the voltage feedback signal becomes
greater than the internal reference ramping up by the soft-start function. After that, the start-up occurs in the
same way the soft-start condition fully discharges, regardless of the SKIPSELx selection.
22
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3.3-V, 10-mA LDO (VREG3)
A 3.3-V, 10-mA, linear regulator is integrated in the TPS51220A-Q1. This LDO services some of the analog
circuit in the device and provides a handy standby supply for 3.3-V Always On voltage in the notebook system.
Apply a 2.2-μF (at least 1-μF), high quality X5R or X7R ceramic capacitor from VREG3 to (signal) GND in
adjacent to the device.
2-V, 100-μA Sink/Source Reference (VREF2)
This voltage is used for the reference of the loop compensation network. Apply a 0.22-μF (at least 0.1-μF),
high-quality X5R or X7R ceramic capacitor from VREF2 to (signal) GND in adjacent to the device.
5.0-V, 100-mA LDO (VREG5)
A 5.0-V, 100-mA, linear regulator is integrated in the TPS51220A-Q1. This LDO services the main analog supply
rail and provides the current for gate drivers until switch-over function becomes enable. Apply a 10-μF (at least
4.7-μF), high-quality X5R or X7R ceramic capacitor from VREG5 to (power) GND in adjacent to the device.
VREG5 SWITCHOVER
When EN1 is high, PGOOD1 indicates GOOD and a voltage of more than 4.83 V is applied to V5SW, the
internal 5V-LDO is shut off and the VREG5 is shorted to V5SW by an internal MOSFET after an 7.7-ms delay.
When the V5SW voltage becomes lower than 4.65 V, EN1 becomes low, or PGOOD1 indicates BAD, the internal
switch is turned off, and the internal 5V-LDO resumes immediately.
BASIC PWM OPERATIONS
The main control loop of the SMPS is designed as a fixed frequency, pulse width modulation (PWM) controller. It
supports two control schemes; a peak current mode and a proprietary D-CAP mode. Current mode achieves
stable operation with any type of output capacitors, including low ESR capacitor(s) such as ceramic or specialty
polymer capacitors. D-CAP mode does not require an external compensation circuit, and is suitable for relatively
larger ESR capacitor(s) configuration. These control schemes are selected with FUNC pin. See Table 4.
CURRENT MODE
The current mode scheme uses the output voltage information and the inductor current information to regulate
the output voltage. The output voltage information is sensed by VFBx pin. The signal is compared with the
internal 1-V reference and the voltage difference is amplified by a transconductance amplifier (VFB-AMP). The
inductor current information is sensed by CSPx and CSNx pins. The voltage difference is amplified by another
transconductance amplifier (CS-AMP). The output of the VFB-AMP indicates the target peak inductor current. If
the output voltage decreases, the TPS51220A-Q1 increases the target inductor current to raise the output
voltage. Alternatively, if the output voltage rises, the TPS51220A-Q1 decreases the target inductor current to
reduce the output voltage.
At the beginning of each clock cycle, the high-side MOSFET is turned on, or becomes ‘ON’ state. The high-side
MOSFET is turned off, or becomes OFF state, after the inductor current becomes the target value which is
determined by the combination value of the output of the VFB-AMP and a ramp compensation signal. The ramp
compensation signal is used to prevent sub-harmonic oscillation of the inductor current control loop. The
high-side MOSFET is turned on again at the next clock cycle. By repeating the operation in this manner, the
controller regulates the output voltage. The synchronous low-side or the rectifying MOSFET is turned on each
OFF state to keep the conduction loss minimum.
D-CAP™ MODE
With the D-CAP mode operation, the PWM comparator compares VREF2 with the combination value of the
COMP voltage, VFB-AMP output, and the ramp compensation signal. When the both signals are equal at the
peak of the voltage sense signal, the comparator provides the OFF signal to the high-side MOSFET driver.
Because the compensation network is implemented on the part and the output waveform itself is used as the
error signal, external circuit is simplified. Another advantage is its inherent fast transient response. A trade-off is
a sufficient amount of ESR required in the output capacitor. The D-CAP™ mode is suitable for relatively larger
output ripple voltage application. The inductor current information is used for the overcurrent protection and light
load operation.
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PWM FREQUENCY CONTROL
The TPS51220A-Q1 has a fixed frequency control scheme with 180° phase shift. The switching frequency can be
determined by an external resistor which is connected between RF pin and GND, and can be calculated using
Equation 1.
1 × 105
fsw éëkHz ùû =
RF ëékΩ ûù
(1)
TPS51220A-Q1 can also synchronize to more than 2.5 V amplitude external clock by applying the signal to the
RF pin. The set timing of channel 1 initiates at the raising edge (1.3 V typ) of the clock and channel 2 initiates at
the falling edge (1.1 V typ). Therefore, the 50% duty signal makes both channels 180° phase shift.
When the external clock synchronization is selected, the following conditions are required.
• Remove RF resistor
• Add clock signal before EN1 or EN2 turning on
The TPS51220A-Q1 does NOT support switching frequency change on-the-fly. (neither from the switching
frequency set by the RF resistor to the external clock, nor vice versa)
1000
900
fSW - Frequency - kHz
800
700
600
500
400
300
200
100
0
100
200
300
400
500
RF - Resistance - kW
Figure 41. Switching Frequency vs RF
180 Degrees Phase Shift and Blanking Time
The two channels of the SMPS operate 180 degrees phase shift. This scheme helps in reducing the input RMS
current. As a result, the device provides the benefits of saving the number and power loss of the input bulk
capacitors. To minimize interaction between the two channels caused by switching noise, blanking time is
implemented. The loop comparator output is masked during the blanking time to avoid false turning off the
channel.
There are two cases where the inter-channel communication can take place:
1. One channel's switching node falling edge is close to another channel's switching node rising edge.
2. One channel's switching node falling edge is close to another channel's switching node falling edge.
In both cases, the TPS51220A-Q1 shows jitter inherent to the blanking time. Since the device is a fixed
frequency controller, the rising edge of the switching node is settled at the clock cycle. Consequently, jitter is
observed at a period of switching node falling edge. This jitter does not represent small signal instability. In fact,
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jittering is a normal action of control loop against timing deviation caused by any accidental event such as noise,
or the blanking time, adjusting back to the regulation point. A small amount of jittering does not harm the voltage
regulation. However; if the user wants a further reduction of jitter, using the external clock synchronization
provides adjustable phase shift between channels to avoid overlapping of switching events. See the PWM
Frequency Control section.
LIGHT LOAD OPERATION
The TPS51220A-Q1 automatically reduces switching frequency at light load conditions to maintain high efficiency
if Auto Skip or Out-of-Audio™ mode is selected by SKIPSELx. This reduction of frequency is achieved by
skipping pulses. As the output current decreases from heavy load condition, the inductor current is also reduced
and eventually comes to the point that its peak reaches a predetermined current, ILL(PEAK), which indicates the
boundary between heavy-load and light-load conditions. Once the top MOSFET is turned on, the TPS51220A-Q1
does not allow it to be turned off until it reaches ILL(PEAK). This eventually causes an overvoltage condition to the
output and pulse skipping. From the next pulse after zero-crossing is detected, ILL(PEAK) is limited by the
ramp-down signal ILL(PEAK)RAMP, which starts from 25% of the overcurrent limit setting (IOCL(PEAK): (see the Current
Protection section) toward 5% of IOCL(PEAK) over one switching cycle to prevent causing large ripple. The
transition load point to the light load operation ILL(DC) can be calculated in Equation 2.
I LL(DC) + I LL(PEAK) * 0.5 I IND(RIPPLE)
(2)
(V - VOUT ) × VOUT
1
IIND(RIPPLE) =
× IN
L × fSW
VIN
where
•
fSW is the PWM switching frequency which is determined by RF resistor setting or external clock
ILL(PEAK)RAMP = (0.2 - 0.13 ´ t ´ fSW )´ IOCL(PEAK )
(3)
(4)
Switching frequency versus output current in the light load condition is a function of L, f, VIN and VOUT, but it
decreases almost proportionally to the output current from the ILL(DC), as described in Equation 2; while
maintaining the switching synchronization with the clock. Due to the synchronization, the switching waveform in
boundary load condition (close to ILL(DC)) appears as a sub-harmonic oscillation; however, it is the intended
operation.
If SKIPSELx is tied to GND, the TPS51220A-Q1 works on a constant frequency of fSW regardless its load current.
Inductor
Current
ILL(PEAK)
ILL(DC)
IIND(RIPPLE)
0
Time
Figure 42. Boundary Between Pulse Skipping and CCM
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ILL(peak) – Inductor Current Limit – A
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20% of IOCL
ILL(PEAK) Ramp Signal
ILL(PEAK) at
Light Load
7% of IOCL
tON
1/fSW
t – Time
Figure 43. Inductor Current Limit at Pulse Skipping
Table 2. Skip Mode Selection
SKIPSELx
OPERATING MODE
GND
Continuous Conduction
VREF2
VREG3
VREG5
Auto Skip
OOA Skip (maximum 7
skips, for <400 kHz)
OOA Skip (maximum 15 skips, for
equal to or greater than 400kHz)
OUT OF AUDIO SKIP OPERATION
Out-Of-Audio™ (OOA) light-load mode is a unique control feature that keeps the switching frequency above
acoustic audible frequencies toward virtually no load condition while maintaining state-of-the-art high conversion
efficiency. When OOA is selected, the switching frequency is kept higher than audible frequency range in any
load condition. The TPS51220A-Q1 automatically reduced switching frequency at light-load conditions. The OOA
control circuit monitors the states of both MOSFETs and forces an ON state if the predetermined number of
pulses are skipped. The high-side MOSFET is turned on before the output voltage declines down to the target
value, so that eventually an overvoltage condition is caused. The OOA control circuit detects this overvoltage
condition and begins modulating the skip-mode on time to keep the output voltage.
The TPS51220A-Q1 supports a wide-switching frequency range, therefore, the OOA skip mode has two
selections. See Table 2. When the 300-kHz switching frequency is selected, a maximum of seven (7) skips
(SKIPSEL=3.3 V) makes the lowest frequency at 37.5 kHz. If a 15-skip maximum is chosen, it becomes 18.8
kHz, hence the maximum 7 skip is suitable for less than 400 kHz, and the maximum 15 skip is 400 kHz or
greater.
99% DUTY CYCLE OPERATION
In a low-dropout condition such as 5-V input to 5-V output, the basic control loop attempts to maintain 100% of
the high-side MOSFET ON. However, with the N-channel MOSFET used for the top switch, it is not possible to
use the 100% on-cycle to charge the boot strap capacitor. When high duty is required, the TPS51220A-Q1
extends the ON period (by skipping a maximum of three clock cycles and reducing the switching frequency to
25% of the steady state value) and asserts the OFF state after extended ON.
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HIGH-SIDE DRIVER
The high-side driver is designed to drive high current, low RDS(on) N-channel MOSFET(s). The drive capability is
represented by its internal resistance, which is 1.7Ω for VBSTx to DRVHx, and 1Ω for DRVHx to SWx. When
configured as a floating driver, 5 V of bias voltage is delivered from VREG5 supply. The instantaneous drive
current is supplied by the flying capacitor between VBSTx and SWx pins. The average drive current is equal to
the gate charge at Vgs = 5V times switching frequency. This gate drive current as well as the low-side gate drive
current times 5 V makes the driving power which needs to be dissipated mainly from TPS51220A-Q1 package. A
dead time to prevent shoot through is internally generated between high-side MOSFET off to low-side MOSFET
on, and low-side MOSFET off to high-side MOSFET on.
LOW-SIDE DRIVER
The low-side driver is designed to drive high-current low-RDS(on) N-channel MOSFET(s). The drive capability is
represented by its internal resistance, which are 1.3Ω for VREG5 to DRVLx and 0.7Ω for DRVLx to GND. The
5-V bias voltage is delivered from VREG5 supply. The instantaneous drive current is supplied by an input
capacitor connected between VREG5 and GND. The average drive current is also calculated by the gate charge
at Vgs = 5 V times switching frequency.
CURRENT SENSING SCHEME
In order to provide both good accuracy and cost effective solution, the TPS51220A-Q1 supports external resistor
sensing and inductor DCR sensing. An RC network with high quality X5R or X7R ceramic capacitor should be
used to extract voltage drop across DCR. 0.1μF is a good value to start the design. CSPx and CSNx should be
connected to positive and negative terminal of the sensing device respectively. TPS51220A-Q1 has an internal
current amplifier. The gain of the current amplifier, Gc, is selected by TRIP terminal. In any setting, the output
signal of the current amplifier becomes 100mV at the OCL setting point. This means that the current sensing
amplifier normalize the current information signal based on the OCL setting. Attaching a RC network
recommended even with a resistor sensing scheme to get an accurate current sensing; see the external parts
selection session for detailed configurations.
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ADAPTIVE ZERO CROSSING
TPS51220A-Q1 has an adaptive zero crossing circuit which performs optimization of the zero inductor current
detection at skip mode operation. This function pursues ideal low-side MOSFET turning off timing and
compensates inherent offset voltage of the ZC comparator and delay time of the ZC detection circuit. It prevents
SW-node swing-up caused by too late detection and minimizes diode conduction period caused by too early
detection. As a result, better light load efficiency is delivered.
CURRENT PROTECTION
TPS51220A-Q1 has cycle-by-cycle overcurrent limiting control. If the inductor current becomes larger than the
overcurrent trip level, TPS51220A-Q1 turns off high-side MOSFET, turns on low-side MOSFET and waits for the
next clock cycle.
IOCL(PEAK) sets peak level of the inductor current. Thus, the dc load current at overcurrent threshold, IOCL(DC), can
be calculated as follows;
I OCL(DC) + I OCL(PEAK) * 0.5 I IND(RIPPLE)
(5)
VOCL
I OCL(PEAK) +
RSENSE
where
•
•
RSENSE is resistance of current sensing device
V(OCL) is the overcurrent trip threshold voltage which is determined by TRIP pin voltages as shown in Table 3
(6)
In an overcurrent condition, the current to the load exceeds the current to the output capacitor thus the output
voltage tends to fall down, and it ultimately crosses the undervoltage protection threshold and shutdown.
Table 3. OCL Trip and Discharge Selection
TRIP
V(OCL) (OCL TRIP VOLTAGE)
DISCHARGE
GND
VREF2
V(OCL-ULV) (ULTRA-LOW VOLTAGE)
Enable
Disable
VREG3
VREG5
V(OCL-LV) (LOW VOLTAGE)
Disable
Enable
POWERGOOD
The TPS51220A-Q1 has powergood output for both switcher channels. The powergood function is activated after
softstart has finished. If the output voltage becomes within ±5% of the target value, internal comparators detect
power good state and the powergood signal becomes high after 1ms internal delay. If the output voltage goes
outside of ±10% of the target value, the powergood signal becomes low after 1.5μs internal delay. Apply voltage
should be less than 6V and the recommended pull-up resistance value is from 100kΩ to 1MΩ.
OUTPUT DISCHARGE CONTROL
The TPS51220A-Q1 discharges output when ENx is low. The TPS51220A-Q1 discharges outputs using an
internal MOSFET which is connected to CSNx and GND. The current capability of these MOSFETs is limited to
discharge the output capacitor slowly. If ENx becomes high during discharge, MOSFETs are turning off, and
some output voltage remains. SMPS changes over to soft-start. The PWM initiates after the target voltage
overtakes the remaining output voltage. This function can be disabled as shown in Table 3.
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OVERVOLTAGE/UNDERVOLTAGE PROTECTION
TPS51220A-Q1 monitors the output voltage to detect overvoltage and undervoltage. When the output voltage
becomes 15% higher than the target value, the OVP comparator output goes high and the circuit latches as the
high-side MOSFET driver OFF and the low-side MOSFET driver ON, and shuts off another channel.
When the feedback voltage becomes lower than 70% of the target voltage, the UVP comparator output goes
high and an internal UVP delay counter begins counting. After 1 ms, TPS51220A-Q1 latches OFF both high-side
and low-side MOSFETs, and shuts off another channel. This UVP function is enabled after soft-start has
completed. OVP function can be disabled as shown in Table 4. The procedures for restarting from these
protection states are:
1. toggle EN
2. toggle EN1 and EN2 or
3. once hit UVLO
Table 4. FUNC Logic States
FUNC
GND
VREF2
VREG3
VREG5
OVP
Enable
Disable
Enable
Disable
CONTROL
SCHEME
Current mode
D-CAP mode
D-CAP mode
Current mode
UVLO PROTECTION
The TPS51220A-Q1 has undervoltage lockout protections (UVLO) for VREG5, VREG3 and VREF2. When the
voltage is lower than UVLO threshold voltage, TPS51220A-Q1 shuts off each output as shown inTable 5. This is
non-latch protection.
Table 5. UVLO Protection
CH1/ CH2
VREG5
VREG3
VREF2
VREG5 UVLO
Off
—
On
On
VREG3 UVLO
Off
Off
—
Off
VREF2 UVLO
Off
Off
On
—
THERMAL SHUTDOWN
The TPS51220A-Q1 monitors the device temperature. If the temperature exceeds the threshold value,
TPS51220A-Q1 shuts off both SMPS and 5V-LDO, and decreases the VREG3 current limitation to 5 mA
(typically). This is non-latch protection.
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APPLICATION INFORMATION
EXTERNAL PARTS SELECTION
A buck converter using the TPS51220A-Q1 consists of linear circuits and a switching modulator. Figure 44 and
Figure 45 show basic scheme.
Voltage divider
R1
VFB
Gmv
DRVH
PWM
Control
logic
&
Driver
+
+
R2
VIN
Switching Modulator
Ramp
comp.
+
+
1.0V
Lx
Rs
DRVL
ESR
RL
Co
COMP
Cc
Rgv
Gmc
Rgc
VREF
CSP
+
+
CSN
2.0V
Error Amplifier
Figure 44. Simplified Current Mode Functional Blocks
Voltage divider
VFB
Gmv
DRVH
PWM
+
+
R2
+
+
1.0V
VIN
Switching Modulator
Ramp
comp.
R1
Control
logic
&
Driver
Lx
Rs
DRVL
ESR
RL
Co
COMP
Rgv
VREF
+
2.0V
Figure 45. Simplified D-CAP Mode Functional Blocks
The external components can be selected by following manner.
1. Determine output voltage dividing resistors. (R1 and R2: shown in Figure 44) using Equation 7 .
R1 + ǒV OUT * 1.0Ǔ
R2
(7)
For D-CAP mode, recommended R2 value is from 10kΩ to 20kΩ.
2. Determine switching frequency. Higher frequency allows smaller output capacitances, however, degrade
efficiency due to increase of switching loss. Frequency setting resistor for RF-pin can be calculated by;
5
RF[kW] + 1 10
ƒ sw [kHz]
(8)
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3. Choose the inductor. The inductance value should be determined to give the ripple current of
approximately 25% to 50% of maximum output current. Recommended ripple current rate is about 30% to
40% at the typical input voltage condition, next equation uses 33%.
(VIN(TYP) - VOUT ) × VOUT
1
L=
×
0.33 x IOUT(MAX) x fSW
VIN(TYP)
(9)
The inductor also needs to have low DCR to achieve good efficiency, as well as enough room above peak
inductor current before saturation.
4. Determine the OCL trip voltage threshold, V(OCL), and select the sensing resistor.
The OCL trip voltage threshold is determined by TRIP pin setting. To use a larger value improves the S/N
ratio. Determine the sensing resistor using next equation. IOCL(PEAK) should be approximately 1.5 × IOUT(MAX)
to 1.7 × IOUT(MAX).
VOCL
R SENSE +
I OCL(PEAK)
(10)
5. Determine Rgv. Rgv should be determined from preferable droop compensation value and is given by next
equation based on the typical number of Gmv = 500μS.
I OUT(MAX)
1
Rgv + 0.1
VOUT
Gmv Vdroop
I OCL(PEAK)
(11)
Rgv[kW] + 200
I OUT(MAX)
I OCL(PEAK)
V OUT[V]
Vdroop[mV]
(12)
If no-droop is preferred, attach a series RC network circuit instead of single resistor. Series resistance is
determined using Equation 12 . Series capacitance can be arbitrarily chosen to meet the RC time constant,
but should be kept under 1/10 of fo. For D-CAP mode, Rgv is used for adjusting ramp compensation. 10kΩ is
a good value to start design with. 6kΩ to 20kΩ can be chosen.
6. Determine output capacitance Co to achieve a stable operation using the next equation. The 0 dB frequency,
fo, should be kept under 1/3 of the switching frequency.
Gmv Rgv
ƒsw
1
ƒ0 + 5
t
p I OCL(PEAK) V
3
Co
OUT
(13)
Co u 15
p
I OCL(PEAK)
1
VOUT
Gmv Rgv
ƒsw
(14)
For D-CAP mode, fo is determined by the output capacitor’s characteristics as below.
ƒsw
1
ƒ0 +
t
3
2p ESR Co
3
Co u
2p ESR ƒsw
(15)
(16)
For better jitter performance, a sufficient amount of feedback signal is required at VFBx pin. The
recommended signal level is approximately 30mV per tsw (switching period) of the ramping up rate, and more
than 4 mV of peak-to-peak voltage.
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VFB
signal
30mV
VFBRIPPLE =VoRIPPLE x 1/Vout
Time
tSW = 1/fSW
Figure 46. Required voltage feedback ramp signal
7. Calculate Cc. The purpose of this capacitance is to cancel zero caused by ESR of the output capacitor. If
ceramic capacitor(s) is used, there is no need for Cc. If a combination of different capacitors is used, attach a
RC network circuit instead of single capacitance to cancel zeros and poles caused by the output capacitors.
With single capacitance, Cc is given in Equation 17.
Cc + Co ESR
Rgv
(17)
For D-CAP mode, basically Cc is not needed.
8. Choose MOSFETs Generally, the on resistance affects efficiency at high load conditions as conduction loss.
For a low output voltage application, the duty ratio is not high enough so that the on resistance of high-side
MOSFET does not affect efficiency; however, switching speed (tr and tf) affects efficiency as switching loss.
As for low-side MOSFET, the switching loss is usually not a main portion of the total loss.
RESISTOR CURRENT SENSING
For more accurate current sensing with an external resistor, the following technique is recommended. Adding an
RC filter to cancel the parasitic inductance of resistor, this filter value is calculated using Equation 18.
Cx Rx + Lx
Rs
(18)
This equation means time-constant of Cx and Rx should match the one of Lx (ESL) and Rs.
VIN
Ex-resistor
DRVH
Control
logic
&
Driver
L
Rs
Lx(ESL)
DRVL
Co
CSP
+
Cx
Rx
CSN
Figure 47. External Resistor Current Sensing
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INDUCTOR DCR CURRENT SENSING
To use inductor DCR as current sensing resistor (Rs), the configuration needs to change as below. However, the
equation that must be satisfied is the same as the one for the resistor sensing.
VIN
Inductor
DRVH
Control
logic
&
Driver
Lx
Rs(DCR)
DRVL
Co
Rx
CSP
+
Cx
CSN
Figure 48. Inductor DCR Current Sensing
VIN
Inductor
DRVH
Control
logic
&
Driver
Lx
Rs(DCR)
DRVL
Co
Rx
CSP
+
Cx
Rc
CSN
Figure 49. Inductor DCR Current Sensing With Voltage Divider
TPS51220A-Q1 has fixed V(OCL) point (60 mV or 31 mV). In order to adjust for DCR, a voltage divider can be
configured a described in Figure 49.
For Rx, Rc and Cx can be calculated as shown below, and overcurrent limitation value can be calculated as
follows:
Lx
Cx × (Rx//Rc ) =
Rs
(19)
Rx
)
Rc
1
I OCL(PEAK) + VOCL
Rs
Rc
(20)
Figure 50 shows the compensation technique for the temperature drifts of the inductor DCR value. This scheme
assumes the temperature rise at the thermistor (RNTC) is directly proportional to the temperature rise at the
inductor.
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Inductor
Lx
Rx
Rs(DCR)
RNTC
Rc1
Rc2
CO
CSP
+
Cx
CSN
Figure 50. Inductor DCR Current Sensing With Temperature Compensate
LAYOUT CONSIDERATIONS
Certain points must be considered before starting a PCB layout work using the TPS51220A-Q1.
Placement
• Place RC network for CSP1 and CSP2 close to the device pins.
• Place bypass capacitors for VREG5, VREG3 and VREF2 close to the device pins.
• Place frequency-setting resistor close to the device pin.
• Place the compensation circuits for COMP1 and COMP2 close to the device pins.
• Place the voltage setting resistors close to the device pins, especially when D-CAP mode is chosen.
Routing (sensitive analog portion)
• Use separate traces for; see Figure 51
– Output voltage sensing from current sensing (negative-side)
– Output voltage sensing from V5SW input (when VOUT = 5V)
– Current sensing (positive-side) from switch-node
V5SW
R1
VFB
R2
H-FET
Inductor
Vout
SW
L-FET
Cout
R
CSP
C
CSN
Figure 51. Sensing Trace Routings
•
34
Use Kelvin sensing traces from the solder pads of the current sensing device (inductor or resistor) to current
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sensing comparator inputs (CSPx and CSNx). (See Figure 52)
Current sensing
Device
RC network
next to IC
Figure 52. Current Sensing Traces
•
•
•
•
Use small copper space for VFBx. These are short and narrow traces to avoid noise coupling
Connect VFB resistor trace to the positive node of the output capacitor.
Use signal GND for VREF2 and VREG3 capacitors, RF and VFB resistors, and the other sensitive analog
components. Placing a signal GND plane (underneath the IC, and fully covered peripheral components) on
the internal layer for shielding purpose is recommended. (See Figure 53)
Use a thermal land for PowerPAD™. Five or more vias, with 0.33-mm (13-mils) diameter connected from the
thermal land to the internal GND plane, should be used to help dissipation. Do NOT connect the GND-pin to
this thermal land on the surface layer, underneath the package.
Routing (power portion)
• Use wider/shorter traces of DRVL for low-side gate drivers to reduce stray inductance.
• Use the parallel traces of SW and DRVH for high-side MOSFET gate drive, and keep them away from DRVL.
• Connect SW trace to source terminal of the high-side MOSFET.
• Use power GND for VREG5, VIN and VOUT capacitors and low-side MOSFETs. Power GND and signal GND
should be connected near the device GND terminal. (See Figure 53)
0W resistor
GND
#28
GND-pin
To inner
Power-GND
layer
To inner
Signal-GND
plane
Inner Signal-GND plane
Figure 53. GND Layout Example
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VO1
5.0V/8A
PGND
C11
L1
VBAT
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GND
R14
7.5k W
EN
32
R16
4.7W
DRVH1
R11
120k W
R15
4.3k W
GND
8
C15
100p F
CSN1
9
CSP1
7
R12
30k W
GND
C13
0.1mF
SKIPSEL1
6
PGOOD1
5
PGOOD1
SKIPSEL1
EN1
RF
V5SW
4
3
2
1
C14
0.1m F
EN1
R01
300k W
Q12
PGND
GND
VO1
VO1
PGND
C12
SW 1
V F B1
31
10
PowerPAD
R13
18k W
VREF2
11
12
14
VREF2
GND VREF2
13
25
C24
0.1 mF
15
R23
12k W
16
CSN2
C25
220p F
17
GND
R22
27k W
R21
62k W
C23
0.1 mF
SKIPSEL2
18
SKIPSEL2
19
CSP2
PGOOD2
VO2
R25
4.3k W
VREG5
R24
6.8k W
GND
21
EN2
20
VREG3
3.3V/10mA
C03
2.2 mF
22
VREG3
PGND
C21
VO2
3.3V/8A
VBAT
EN2
PGND
L2
23
24
Q22
PGND
C22
VBAT
VIN
DRVH2
R26
4.7W
Q21
PGOOD2
26
27
GND
C02
0.22 mF
TPS51220ARTV
(QFN32)
28
29
PGND
30
PGND
C01
10mF
DR V L1
FU NC
VREG5
5V/100mA
V BS T 1
CO M P 1
VR EG5
EN
DR V L2
CO MP 2
GN D
V R E F2
V BS T2
TR IP
SW 2
36
V FB 2
Q11
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
APPLICATION CIRCUITS
Figure 54. Current Mode, DCR Sensing, 5-V/8-A, 3.3-V/8-A, 330-kHz
Copyright © 2011, Texas Instruments Incorporated
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Table 6. Current Mode, DCR Sensing, 5-V/8-A, 3.3-V/8-A, 330-kHz
SYMBOL
SPECIFICATION
MANUFACTURER
PART NUMBER
C11
2 × 330 μF, 6.3 V, 18 mΩ
Sanyo
6TPE330MIL
C12
2 × 10 μF, 25 V
Murata
GRM32DR71E106K
C21
470 μF, 4.0V, 15 mΩ
Sanyo
4TPE470MFL
C22
2 × 10 μF, 25 V
Murata
GRM32DR71E106K
L1
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
L2
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
Q11, Q21
30-V, 12 A, 10.5 mΩ
Fairchild
FDMS8692
Q12, Q22
30 V, 18 A, 5.4 mΩ
Fairchild
FDMS8672AS
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37
VO1
5.0V/8A
PGND
C11
L1
VBAT
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GND
R14
7.5k W
EN
R16
4.7W
32
R11
120k W
R15
4.3k W
GND
8
CSN1
C15
1.8n F
9
CSP1
7
R12
30k W
GND
C13
0.1mF
SKIPSEL1
6
PGOOD1
5
PGOOD1
SKIPSEL1
EN1
4
RF
3
DRVH1
V5SW
2
1
C14
0.1m F
EN1
R01
300k W
Q12
PGND
GND
VO1
VO1
PGND
C12
SW 1
V F B1
31
10
PowerPAD
VREF2
R13
10k W
11
12
GND
13
14
VREF2
VREF2
25
C24
0.1 mF
15
C25
1.8n F
R23
9.1k W
16
CSN2
17
GND
R22
27k W
R21
62k W
C23
0.1 mF
SKIPSEL2
18
SKIPSEL2
19
CSP2
PGOOD2
VO2
R25
4.3k W
VREG5
R24
6.8k W
GND
21
EN2
20
VREG3
3.3V/10mA
C03
2.2 mF
22
VREG3
PGND
C21
VO2
3.3V/8A
VBAT
EN2
PGND
L2
23
24
Q22
PGND
C22
VBAT
VIN
DRVH2
R26
4.7W
Q21
PGOOD2
26
27
GND
C02
0.22 mF
TPS51220ARTV
(QFN32)
28
29
PGND
30
PGND
C01
10mF
DR V L1
FU NC
VREG5
5V/100mA
V BS T 1
CO M P 1
VR EG5
EN
DR V L2
CO MP 2
GN D
V R E F2
V BS T2
TR IP
SW 2
38
V FB 2
Q11
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Figure 55. Current Mode (Non-Droop), DCR Sensing, 5-V/8-A, 3.3-V/8-A, 330-kHz
Copyright © 2011, Texas Instruments Incorporated
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Table 7. Current Mode (Non-droop), DCR Sensing, 5-V/8-A, 3.3-V/8-A, 330-kHz
SYMBOL
SPECIFICATION
MANUFACTURER
PART NUMBER
C11
2 x 330 μF, 6.3 V 18 mΩ
Sanyo
6TPE330MIL
C12
2 x 10 μF, 25 V
Murata
GRM32DR71E106K
C21
470 μF, 4.0V, 15 mΩ
Sanyo
4TPE470MFL
C22
2 x 10 μF, 25 V
Murata
GRM32DR71E106K
L1
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
L2
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
Q11, Q21
30-V, 12-A, 10.5 mΩ
Fairchild
FDMS8692
Q12, Q22
30-V, 18-A, 5.4 mΩ
Fairchild
FDMS8672AS
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39
VO1
5.0V/8A
PGND
C11
R14
7.5k W
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EN
R16
4.7W
32
R11
120k W
R15
4.3k W
GND
8
CSN1
9
CSP1
7
R12
30k W
GND
C13
0.1mF
SKIPSEL1
6
PGOOD1
5
PGOOD1
SKIPSEL1
EN1
4
RF
3
DRVH1
V5SW
2
1
C14
0.1m F
EN1
R01
300k W
Q12
PGND
GND
VO1
VO1
PGND
C12
VREG5
5V/100mA
SW 1
V F B1
31
10
PowerPAD
VREF2
R13
10k W
11
12
14
VREF2
GND VREF2
13
25
C24
0.1 mF
15
R23
10k W
16
CSN2
17
GND
R22
27k W
R21
62k W
C23
0.1 mF
SKIPSEL2
18
SKIPSEL2
19
CSP2
PGOOD2
VO2
R25
4.3k W
VREG5
R24
6.8k W
GND
21
EN2
20
VREG3
3.3V/10mA
C03
2.2 mF
22
VREG3
PGND
C21
VO2
3.3V/8A
VBAT
EN2
PGND
L2
23
24
Q22
PGND
C22
VBAT
VIN
DRVH2
R26
4.7W
Q21
PGOOD2
26
27
GND
C02
0.22 mF
TPS51220ARTV
(QFN32)
28
29
PGND
30
PGND
C01
10mF
DR V L1
FU NC
Q11
V BS T 1
CO M P 1
VR EG5
EN
DR V L2
CO MP 2
GN D
V R E F2
V BS T2
TR IP
SW 2
V FB 2
40
VREG3
L1
VBAT
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Figure 56. D-CAP Mode, DCR Sensing, 5-V/8-A, 3.3-V/8-A, 330-kHz
Copyright © 2011, Texas Instruments Incorporated
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Table 8. D-CAP Mode, DCR Sensing, 5-V/ 8-A, 3.3-V/8-A, 330-kHz
SYMBOL
SPECIFICATION
MANUFACTURER
PART NUMBER
C11
2 x 330 μF, 6.3 V, 18 mΩ
Sanyo
6TPE330MIL
C12
2 x 10 μF, 25 V
Murata
GRM32DR71E106K
C21
470 μF, 4.0V, 15 mΩ
Sanyo
4TPE470MFL
C22
2 x 10 μF, 25 V
Murata
GRM32DR71E106K
L1
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
L2
3.3 μH, 10.7 A, 10.5 mΩ
TOKO
FDV1040-3R3M
Q11, Q21
30 V, 12 A, 10.5 mΩ
Fairchild
FDMS8692
Q12, Q22
30 V, 18 A, 5.4 mΩ
Fairchild
FDMS8672AS
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VO1
5.0V/5A
PGND
C11
L1
VBAT
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GND
R14
6.8k W
EN
32
R16
4.7W
DRVH1
R11
120k W
R15
56k W
GND
8
C15
100p F
CSN1
9
CSP1
7
R12
30k W
GND
C13
0.1mF
SKIPSEL1
6
PGOOD1
5
PGOOD1
SKIPSEL1
EN1
RF
V5SW
4
3
2
1
C14
0.1m F
EN1
R01
330k W
Q12
PGND
GND
VO1
VO1
PGND
C12
SW 1
V F B1
31
10
PowerPAD
R13
10k W
VREF2
11
12
14
VREF2
GND VREF2
13
25
C24
0.1 mF
15
R23
10k W
16
17
C25
220p F
CSN2
GND
R22
27k W
R21
62k W
C23
0.1 mF
SKIPSEL2
18
SKIPSEL2
19
CSP2
PGOOD2
VO2
R25
56k W
VREG5
R24
6.8k W
GND
21
EN2
20
VREG3
3.3V/10mA
C03
2.2 mF
22
VREG3
PGND
C21
VO2
3.3V/5A
VBAT
EN2
PGND
L2
23
24
Q22
PGND
C22
VBAT
VIN
DRVH2
R26
4.7W
Q21
PGOOD2
26
27
GND
C02
0.22 mF
TPS51220ARTV
(QFN32)
28
29
PGND
30
PGND
C01
10mF
DR V L1
FU NC
VREG5
5V/100mA
V BS T 1
CO M P 1
VR EG5
EN
DR V L2
CO MP 2
GN D
V R E F2
V BS T2
TR IP
SW 2
42
V FB 2
Q11
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Figure 57. Current Mode, DCR Sensing, 5-V/5-A, 3.3-V/5-A, 300-kHz
Copyright © 2011, Texas Instruments Incorporated
TPS51220A-Q1
SLUSAI2 – MARCH 2011
www.ti.com
Table 9. Current Mode, DCR Sensing, 5-V/5-A, 3.3-V/5-A, 300-kHz
SYMBOL
SPECIFICATION
MANUFACTURER
PART NUMBER
C11
2 × 120 μF, 6.3V, 15 mΩ
Panasonic
EEFCX0J121R
C12
2 × 10 μF, 25 V
Murata
GRM32DR71E106K
C21
2 × 220 μF, 4.0 V, 15 mΩ
Panasonic
EEFCX0G221R
C22
2 × 10 μF, 25 V
Murata
GRM32DR71E106K
L1
4.0 μH, 10.3 A, 6.6 mΩ
Sumida
CEP125-4R0MC-H
L2
4.0 μH, 10.3 A, 6.6 mΩ
Sumida
CEP125-4R0MC-H
Q11, Q21
30 V, 13.6 A, 9.5 mΩ
IR
IRF7821
Q12, Q22
30 V, 13.8 A, 5.8 mΩ
IR
IRF8113
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43
PACKAGE OPTION ADDENDUM
www.ti.com
28-Aug-2012
PACKAGING INFORMATION
Orderable Device
TPS51220ATRTVRQ1
Status
(1)
Package Type Package
Drawing
ACTIVE
WQFN
RTV
Pins
Package Qty
32
3000
Eco Plan
(2)
Green (RoHS
& no Sb/Br)
Lead/
Ball Finish
MSL Peak Temp
(3)
Samples
(Requires Login)
CU NIPDAU Level-3-260C-168 HR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
OTHER QUALIFIED VERSIONS OF TPS51220A-Q1 :
• Catalog: TPS51220A
NOTE: Qualified Version Definitions:
• Catalog - TI's standard catalog product
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
28-Aug-2012
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
TPS51220ATRTVRQ1
Package Package Pins
Type Drawing
WQFN
RTV
32
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
3000
330.0
12.4
Pack Materials-Page 1
5.3
B0
(mm)
K0
(mm)
P1
(mm)
5.3
1.5
8.0
W
Pin1
(mm) Quadrant
12.0
Q2
PACKAGE MATERIALS INFORMATION
www.ti.com
28-Aug-2012
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
TPS51220ATRTVRQ1
WQFN
RTV
32
3000
367.0
367.0
35.0
Pack Materials-Page 2
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