50
60
70
80
90
100
0 2500 5000 7500 10000 12500 15000
EFFICIENCY (%)
OUTPUT CURRENT (mA)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C001
V
IN
= 3.8V
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
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LP8755
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LP8755 Multi-Phase Six-Core Step-Down Converter
Check for Samples: LP8755
1 Features 3 Description
The LP8755 is designed to meet the power
1 Six High-Efficiency Step-Down DC-DC Converter management requirements of the latest applications
Cores: processors in mobile phones and similar portable
Max Output Current 15 A applications. The device contains six step-down DC-
Cores Bundled to a 6-Phase Converter DC converter cores, which are bundled together in a
6-phase buck converter. The device is fully controlled
Load Current Reporting by a SmartReflex™-compatible (DVS) interface or an
Programmable Overcurrent Protection (OCP) I2C-compatible serial interface.
Auto PWM/PFM and Forced-PWM Operations The automatic PWM/PFM operation together with the
and Automatic Low Power-Mode Setting automatic phase adding/shedding maximizes
Automatic Phase Adding/Shedding efficiency over a wide output current range. The
LP8755 supports remote differential voltage sensing
Remote Differential Feedback Voltage Sensing to compensate IR drop between the regulator output
Output Voltage Ramp Control and the point-of-load thus improving the accuracy of
VOUT Range = 0.6 V to 1.67 V the output voltage.
I2C-Compatible Interface which Supports Standard The protection features include short-circuit
(100 kHz), Fast (400 kHz), and High-Speed (3.4 protection, current limits, input OVP, UVLO,
MHz) Modes temperature warning, and shutdown functions.
Four Selectable I2C Addresses Several error flags are provided for status information
of the IC. In addition, I2C read-back includes total
Interrupt Function with Programmable Masking load current and load current for each buck core: The
Output Short-Circuit and Input Overvoltage LP8755 has the ability to sense current being
Protection (OVP) delivered to the load without the addition of current
Spread Spectrum and Phase Control for EMI sense resistors. During start-up, the device controls
Reduction the output voltage slew rate to minimize overshoot
and the inrush current.
Overtemperature Protection (OTP)
Undervoltage Lockout (UVLO) Device Information(1)
PART NUMBER PACKAGE BODY SIZE (MAX)
2 Applications LP8755 DSBGA (49) 3.022 mm x 2.882 mm
Smart Phones, eBooks and Tablets (1) For all available packages, see the orderable addendum at
GSM, GPRS, EDGE, LTE, CDMA and WCDMA the end of the datasheet.
Handsets Efficiency vs. Load Current
Gaming Devices
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
LP8755
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
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Table of Contents
7.3 Features Descriptions............................................. 16
1 Features.................................................................. 17.4 Device Functional Modes........................................ 25
2 Applications ........................................................... 17.5 Programming .......................................................... 27
3 Description............................................................. 17.6 Register Maps......................................................... 29
4 Revision History..................................................... 28 Application and Implementation ........................ 38
5 Pin Configuration and Functions......................... 38.1 Application Information............................................ 38
6 Specifications......................................................... 58.2 Typical Application.................................................. 38
6.1 Absolute Maximum Ratings ..................................... 59 Power Supply Recommendations...................... 47
6.2 ESD Ratings.............................................................. 510 Layout................................................................... 47
6.3 Recommended Operating Conditions ...................... 510.1 Layout Guidelines ................................................. 47
6.4 Thermal Information.................................................. 610.2 Layout Example .................................................... 48
6.5 General Electrical Characteristics............................. 711 Device and Documentation Support................. 49
6.6 6-Phase Buck Electrical Characteristics................... 811.1 Device Support...................................................... 49
6.7 6-Phase Buck System Characteristics...................... 911.2 Documentation Support ....................................... 49
6.8 Protection Features Characteristics........................ 11 11.3 Trademarks........................................................... 49
6.9 I2C Serial Bus Timing Parameters.......................... 12 11.4 Electrostatic Discharge Caution............................ 49
6.10 Typical Characteristics ......................................... 14 11.5 Glossary................................................................ 49
7 Detailed Description............................................ 15 12 Mechanical, Packaging, and Orderable
7.1 Overview................................................................. 15 Information ........................................................... 49
7.2 Functional Block Diagram....................................... 16
4 Revision History
Changes from Original (November 2013) to Revision A Page
Changed formatting to match new TI datasheet guidelines; added Device Information and ESD Ratings tables,
Power Supply Recommendations, Layout, and Device and Documentation Support sections; moved some curves to
Application Curves section, reformatted Detailed Description and Application and Implementation sections, adding
additional content. ................................................................................................................................................................. 1
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F
E
D
C
B
SW
B3
INT
FB
B0+/B0
NSLP
SW
B0
SW
B0
GND
B1/B2 GND
B1/B2
SW
B2
SW
B2
VIN
B2 SDA
SYS VDDA
5V
SCL
SYS
FB
B3+/B3
SW
B4
VIN
B0/B1
VIN
B2
ADDR
GND
B4/B5
FB
B3-/B4 SCL
SR
FB
B5
VIN
B0/B1
SW
B1
VIN
B0/B1
SW
B1
FB
B0-/B1
FB
B2 NRST
SW
B5
GND
B4/B5
VIN
B3/B4
GND
B1/B2
SDA
SR
VIN
B3/B4
GND
B3
VIO
SYS
GNDA
VLDO
GND
B0
GND
B0
1
2
3
4
5
6
7
G
SW
B3
VIN
B5
SW
B4
SW
B5
GND
B4/B5
VIN
B3/B4
GND
B3
A
BUCK2
BUCK1
BUCK0
BUCK5
BUCK4
BUCK3
LP8755
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SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
5 Pin Configuration and Functions
DSBGA (YFQ)
49 Pins
Top View
Pin Functions
PIN TYPE DESCRIPTION
NUMBER NAME
Input for Buck 2. The separate power pins VINBXX are not connected together internally -
A1, B1 VINB2 P VINBXX pins must be connected together in the application and be locally bypassed.
A2, B2 SWB2 A Buck 2 switch node
A3, B3, C3 GNDB1/B2 G Power Ground for Buck 1 and Buck 2
A4, B4 SWB1 A Buck 1 switch node
Input for Buck 0 and Buck 1. The separate power pins VINBXX are not connected together
A5, B5, C5 VINB0/B1 P internally - VINBXX pins must be connected together in the application and be locally bypassed.
A6, B6 SWB0 A Buck 0 switch node
A7, B7 GNDB0 G Power Ground for Buck 0
C1 SDASYS D/I/O Serial interface data input and output for system access. Connect a pullup resistor.
C2 SCLSYS D/I Serial interface clock input for system access. Connect a pullup resistor.
Serial bus address selection. Connect to GND (addr = 60h), VIOSYS (addr = 61h), SDASYS
C4 ADDR D/I (addr = 62h) or SCLSYS (addr = 63h).
Full Power to Low Power state transition control signal (By default active LOW for Low-Power
C6 NSLP D/I PFM mode)
Internal supply voltage capacitor pin. A ceramic low ESR 1-µF capacitor should be connected
C7 VLDO A from this pin to GNDA. The LDO voltage is generated internally, do NOT supply or load this pin
externally.
D1 FBB5 A Not used for six-phase converter. Connect to GND.
D2 FBB3/B4 A Not used for six-phase converter. Connect to GND.
D3 FBB3+/B3 A Not used for six-phase converter. Connect to GND.
D4 FBB2 A Not used for six-phase converter. Connect to GND.
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Pin Functions (continued)
PIN TYPE DESCRIPTION
NUMBER NAME
Remote sensing (negative). Connect to the respective sense pin of the processor or to the
D5 FBB0/B1 A negative power supply trace of the processor as close as possible to the processor.
Remote sensing (positive). Connect to the respective sense pin of the processor or to the
D6 FBB0+/B0 A positive power supply trace of the processor as close as possible to the processor.
D7 GNDA G Ground
Serial Interface data input and output for Dynamic Voltage Scaling (DVS). Connect a pullup
E1 SDASR D/I/O resistor / connect to GND if not used.
E2 SCLSR D/I Serial Interface clock input for DVS. Connect a pullup resistor / connect to GND if not used.
E3, F3, G3 GNDB4/B5 G Power Ground for Buck 4 and Buck 5
E4 NRST A Voltage reference input for DVS interface. Setting NRST input HIGH triggers start-up sequence.
Input for Buck 3 and Buck 4.The separate power pins VINBXX are not connected together
E5, F5, G5 VINB3/B4 P internally - VINBXX pins must be connected together in the application and be locally bypassed.
E6 INT D/O Open-drain interrupt output. Active LOW. Connect a pullup resistor to I/O supply.
This pin shall be tied to the system I/O-voltage. Bias supply voltage for the device. Enables the
I/O interface: All registers are accessible via serial bus interface when this pin is pulled high. An
E7 VIOSYS A internal power-on reset (POR) occurs when VIOSYS is toggled low/high. The I2C host should
allow at least 500 µs before sending data to the LP8755 after the rising edge of the VIOSYS line.
F1 VDDA5V P Input for Analog blocks
F2, G2 SWB5 A Buck 5 switch node
F4, G4 SWB4 A Buck 4 switch node
F6, G6 SWB3 A Buck 3 switch node
F7, G7 GNDB3 G Power Ground for Buck 3
Input for Buck 5. The separate power pins VINBXX are not connected together internally -
G1 VINB5 P VINBXX pins must be connected together in the application and be locally bypassed.
A: Analog Pin, D: Digital Pin, G: Ground Pin, P: Power Pin, I: Input Pin, O: Output Pin
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6 Specifications
6.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)(1)(2)
MIN MAX UNIT
INPUT VOLTAGE
Voltage on power connections (VIOSYS, VDDA5V, VINBXX) 0.3 6 V
Voltage on logic pins (input or output pins) (SCLSYS, SDASYS, NRST, 0.3 6
NSLP, ADDR, INT, SCLSR, SDASR)
Buck switch nodes (SWBXX) 0.3 (VVINBXX + 0.2 V) with 6 V max V
VLDO, FBB0+/B0, FBB0/B1, FBB2, FBB3+/B3, FBB3/B4, FBB5 0.3 2 V
All other analog pins 0.3 6
TEMPERATURE
Junction temperature (TJ-MAX) 150
Maximum lead temperature (soldering, 10 s)(3) 260 °C
Storage temperature, Tstg 65 150
(1) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of
device reliability and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or
other conditions beyond those indicated in the Recommended Operating Conditions is not implied. The Recommended Operating
Conditions indicate conditions at which the device is functional and the device should not be operated beyond such conditions. If
Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and
specifications.
(2) All voltage values are with respect to network ground pin.
(3) For detailed soldering specifications and information, please refer to Texas Instruments AN-1112: DSBGA Wafer-Level Chip-Scale
Package (SNVA009).
6.2 ESD Ratings VALUE UNIT
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001(1) ±1000
Electrostatic
V(ESD) V
discharge Charged-device model (CDM), per JEDEC specification JESD22-C101(2) ±250
(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
6.3 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)(1)(2)
MIN MAX UNIT
INPUT VOLTAGE
Voltage on power connections (VDDA5V, VINBXX) 2.5 5 V
1.8 smaller of 3.3 V or
Voltage on VIOSYS V
VVINBXX
SCLSYS, SDASYS, ADDR 0 VVIOSYS V
SCLSR, SDASR, NSLP, INT 0 VNRST V
NRST 0 1.8 V
TEMPERATURE
Junction temperature (TJ)40 125 °C
Ambient temperature (TA)(3) 40 85
(1) Absolute Maximum Ratings indicate limits beyond which damage to the device may occur, including inoperability and degradation of
device reliability and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or
other conditions beyond those indicated in the Recommended Operating Conditions is not implied. The Recommended Operating
Conditions indicate conditions at which the device is functional and the device should not be operated beyond such conditions. If
Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for availability and
specifications.
(2) All voltage values are with respect to network ground pin.
(3) Junction-to-ambient thermal resistance value given is valid for High-K PCB, and is highly application and board-layout dependent. In
applications where high maximum power dissipation exists, special care must be paid to thermal dissipation issues in board design.
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6.4 Thermal Information LP8755
THERMAL METRIC(1) YFQ UNIT
49 PINS
RθJA Junction-to-ambient thermal resistance(2) 49.2
RθJCtop Junction-to-case (top) thermal resistance(3) 0.2
RθJB Junction-to-board thermal resistance(4) 6.6 °C/W
ψJT Junction-to-top characterization parameter(5) 2.9
ψJB Junction-to-board characterization parameter(6) 6.5
RθJCbot Junction-to-case (bottom) thermal resistance(7) n/a
(1) For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
(2) The junction-to-ambient thermal resistance under natural convection is obtained in a simulation on a JEDEC-standard, high-K board, as
specified in JESD51-7, in an environment described in JESD51-2a.
(3) The junction-to-case (top) thermal resistance is obtained by simulating a cold plate test on the package top. No specific JEDEC standard
test exists, but a close description can be found in the ANSI SEMI standard G30-88.
(4) The junction-to-board thermal resistance is obtained by simulating in an environment with a ring cold plate fixture to control the PCB
temperature, as described in JESD51-8.
(5) The junction-to-top characterization parameter, ψJT, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining RθJA, using a procedure described in JESD51-2a (sections 6 and 7).
(6) The junction-to-board characterization parameter, ψJB, estimates the junction temperature of a device in a real system and is extracted
from the simulation data for obtaining RθJA , using a procedure described in JESD51-2a (sections 6 and 7).
(7) The junction-to-case (bottom) thermal resistance is obtained by simulating a cold plate test on the exposed (power) pad. No specific
JEDEC standard test exists, but a close description can be found in the ANSI SEMI standard G30-88.
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6.5 General Electrical Characteristics
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP)
values at TA= 25°C (unless otherwise noted). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless
otherwise noted).(1)(2)
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
CURRENTS
Shutdown supply current.
Total current into power
ISHDN VVIOSYS = 0 V, VNRST = 0 V 0.1 2
connections VDDA5V and
VINBXX µA
Standby mode supply current.
Total current into power
ISTBY VVIOSYS = 1.8 V, VNRST = 0 V 80
connections VDDA5V and
VINBXX
Active mode current PFM Mode, no load, one core active 0.4
consumption. Total current
IActive mA
Forced PWM Mode, no load, one core
into power connections 14.5
active
VDDA5V and VINBXX
LOGIC AND CONTROL INPUTS SCLSYS, SDASYS, ADDR
0.3 x
VIL Input low level VVIOSYS = 1.8 V to 3.3 V VVIOSYS
VIH Input high level VVIOSYS = 1.8 V to 3.3 V 0.7 x VVIOSYS V
Hysteresis of Schmitt trigger
Vhys 0.1 x VVIOSYS
inputs (SCLSYS, SDASYS)
CiCapacitance of pins See(3) 4 pF
LOGIC AND CONTROL INPUTS SCLSR, SDASR, NSLP, NRST
VIL Input low level VNRST = 1.8 V 0.3 x VNRST
VIH Input high level VNRST = 1.8 V 0.7 x VNRST V
Hysteresis of Schmitt trigger
Vhys 0.1 x VNRST
inputs (SCLSR, SDASR)
Capacitance of SCLSR and
Ci4 pF
SDASR pins
RIN Input resistance NRST pulldown resistor to GND 1200 k
VIL_NRST Input low level NRST 0.54 V
VIH_NRST Input high level NRST 1.3
LOGIC AND CONTROL OUTPUTS
Voltage on INT pin, ISINK = 3 mA, 0.4
VNRST = VVIOSYS = 1.8 V
VOL Output low level V
Voltage on SDASYS, SDASR, ISINK = 3
mA, 0.36
VNRST = VVIOSYS = 1.8 V
RPExternal pullup resistor for INT To I/O Supply 10 k
ALL LOGIC AND CONTROL INPUTS
All logic inputs over pin voltage range.
Note that NRST pin does have an 1.2-MΩ
ILEAK Input current internal pulldown resistor and current 1 1 µA
through this resistor is not included into
ILEAK rating. TA= 25°C
(1) All voltage values are with respect to network ground pin.
(2) Minimum (Min) and Maximum (Max) limits are specified by design, test, or statistical analysis. Typical (Typ.) numbers are not ensured,
but do represent the most likely norm.
(3) Maximum capacitance of SCLSYS or SDASYS line is 8 pF, if ADDR pin is connected to line for serial bus address selection.
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6.6 6-Phase Buck Electrical Characteristics
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP)
values at TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless
otherwise noted).
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
PWM Mode, VOUTSET = 0.6 V to 1.67 V, 0.975 x 1.025 x
VOUTSET
IOUT 15 A(5) VOUTSET VOUTSET
Differential feedback PFM Mode, VOUTSET = 0.6 V to 1.67 V, 0.975 x 1.025 x
VOUTSET
VFB voltage(3)(4) IOUT 375 mA VOUTSET VOUTSET V
VFB0+/B0 - VFB0-/B1 Low-Power PFM Mode, VOUTSET = 0.6 V 0.97 x 1.03 x
to 1.67 V, VOUTSET
VOUTSET VOUTSET
IOUT 30 mA
ILIMITP High side switch current limit 3-A register setting(4) 2700 3200 3700 mA
ILIMITN Low side switch current limit Reverse current(4) 650 850 1050
Range, programmable by register setting 0.6 1.67 V
VOUT Output voltage Step 10 mV
2.5 V VVINBXX 5 V, 0.6 V VOUTSET <2.7 3 3.4
0.8 V (4)
fSW Switching frequency MHz
2.5 V VVINBXX 5 V, 0.8 V VOUTSET 3.6 4 4.5
1.67 V (4)
Test current = 200 mA; Split FET 120
RDSON_P Pin-pin resistance for PFET Test current = 200 mA; Full FET 60 m
RDSON_N Pin-pin resistance for NFET IOUT = –200 mA 50
ILK_HS High-side leakage current VSW = 0 V, Per Buck Core 2 µA
ILK_LS Low-side leakage current VSW = 3.7 V = VVINBXX, per buck core 2
Enabled via control register, Active only
RPD Pull-down resistor 250
when converter disabled, Per Buck Core
Differential feedback Input
RIN_FB TA= 25°C 200 300 400 k
resistance(6)
(1) Junction-to-ambient thermal resistance value given is valid for High-K PCB, and is highly application and board-layout dependent. In
applications where high maximum power dissipation exists, special care must be paid to thermal dissipation issues in board design.
(2) Low-ESR Surface-Mount Ceramic Capacitors (MLCCs) used in setting electrical characteristics. The performance of the LP8755 device
depends greatly on the care taken in designing the Printed Wiring Board (PWB). The use of low inductance and low serial resistance
ceramic capacitors is strongly recommended, while proper grounding is crucial. Attention should be given to decoupling the power
supplies. Decoupling capacitors must be connected close to the IC and between the power and ground pins to support high peak
currents being drawn from System Power Rail during turn-on of the switching MOSFETs. Keep input and output traces as short as
possible, because trace inductance, resistance and capacitance can easily become the performance limiting items.
(3) Due to the nature of the converter operating in PFM Mode/Low-Power Mode, the feedback voltage accuracy specification is for the lower
point of the ripple. Thus the converter will position the average output voltage typically slightly above the nominal PWM-Mode output
voltage.
(4) Datasheet min/max specification limits are specified by design, test, or statistical analysis.
(5) The power switches in the LP8755 are designed to operate continuously with currents up to the switch current limit thresholds. However,
when continuously operating at high current levels there will be significant heat generated within the IC and thus sustained total DC
current which the device can support is typically limited by thermal constraints. Thermal issues will become extremely important when
designing PCB and the thermal environment of the LP8755. PCB with high thermal efficiency is required to ensure the junction
temperature is kept below 125°C. Completing thermal analyses in early stages of the product design process is highly recommended to
predict thermal performance at board level. Under high current load conditions the serial bus master device must monitor the
temperature of the converter using the Thermal warning feature, see Protection Features Characteristics. If the 2nd thermal warning is
triggered at 120°C, the application must quickly decrease the load current to keep the converter within its recommended operating
temperature.
(6) Datasheet min/max specification limits are specified by design.
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6.7 6-Phase Buck System Characteristics
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP)
values at TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless
otherwise noted).
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
Programmable via control register(3)
RAMP_B0[2:0] = 000 30
RAMP_B0[2:0] = 001 15
RAMP_B0[2:0] = 010 7.5
KRAMP Ramp timer RAMP_B0[2:0] = 011 3.8 mV/µs
RAMP_B0[2:0] = 100 1.9
RAMP_B0[2:0] = 101 0.94
RAMP_B0[2:0] = 110 0.47
RAMP_B0[2:0] = 111 0.23
TSTART Start-up time Time from NRST-HIGH to start of switching 25 µs
TRAMP VOUT rise time Time to ramp from 5% to 95% of VOUT 20 µs
Average output current, programmable via
control register, VOUT = 1.1 V. (4)
PFM_EXIT_B0[2:0] = 000 100
PFM_EXIT_B0[2:0] = 001 125
PFM_EXIT_B0[2:0] = 010 150
PFM-to-PWM switch–over
IPFM–PWM mA
current threshold PFM_EXIT_B0[2:0] = 011 175
PFM_EXIT_B0[2:0] = 100 225
PFM_EXIT_B0[2:0] = 101 275
PFM_EXIT_B0[2:0] = 110 325
PFM_EXIT_B0[2:0] = 111 375
Average output current, programmable via
control register, VOUT = 1.1 V. (4)
PFM_ENTRY_B0[2:0] = 000 50
PFM_ENTRY_B0[2:0] = 001 75
PFM_ENTRY_B0[2:0] = 010 100
PWM-to-PFM switchover current
IPWM–PFM mA
threshold PFM_ENTRY_B0[2:0] = 011 125
PFM_ENTRY_B0[2:0] = 100 175
PFM_ENTRY_B0[2:0] = 101 225
PFM_ENTRY_B0[2:0] = 110 275
PFM_ENTRY_B0[2:0] = 111 325
ADD_PH_B0[2:0] = 001 400
ADD_PH_B0[2:0] = 010 500
ADD_PH_B0[2:0] = 011 600
IADD Phase adding level ADD_PH_B0[2:0] = 100 700 mA
ADD_PH_B0[2:0] = 101 800
ADD_PH_B0[2:0] = 110 900
ADD_PH_B0[2:0] = 111 1000
(1) Junction-to-ambient thermal resistance value given is valid for High-K PCB, and is highly application and board-layout dependent. In
applications where high maximum power dissipation exists, special care must be paid to thermal dissipation issues in board design.
(2) Specifications listed in this table are for 6-phase configuration only. Besides the default 6-phase, single-output voltage rail configuration,
the 6 switcher cores can be bundled to a variety of different grouping configurations. For applications requiring other DC-DC converter
configuration(s), please contact the Texas Instruments Sales Office/Distributors for availability and specifications.
(3) In the real application, achievable output voltage ramp profiles are influenced by a number of factors, including the amount of output
capacitance, the load current level, the load characteristic (either resistive or constant-current), and the voltage ramp amplitude. Typical
values are measured with typical conditions. The falling edge ramp rate can be limited by the negative current limit ILIMITN.
(4) The final PFM-to-PWM and PWM-to-PFM switchover current varies slightly and is dependant on the output voltage, input voltage, and
the inductor current level. Typical values are measured with typical conditions.
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6-Phase Buck System Characteristics (continued)
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP)
values at TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless
otherwise noted).
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
SHED_PH_B0[2:0] = 000 300
SHED_PH_B0[2:0] = 001 400
SHED_PH_B0[2:0] = 010 500
ISHED Phase shedding level SHED_PH_B0[2:0] = 011 600 mA
SHED_PH_B0[2:0] = 100 700
SHED_PH_B0[2:0] = 101 800
SHED_PH_B0[2:0] = 110 900
2.5 V VVINBXX 5 V
Line regulation 0.05 %/V
ILOAD = 1 A, forced PWM
Load regulation in PWM mode of 100 mA ILOAD 10 A, Differential sensing 0.2 %/A
operation enabled
AUTO (no Low-Power PFM) mode, IOUT 0.5 ±30 mV
mA 500 mA 0.5 mA, 100 ns load step
ΔVOUT PWM mode, IOUT 0.6 A 2 A 0.6 A, 400-ns
Transient load step response ±20 mV
load step
PWM mode, IOUT 1 A 8 A 1 A, 400-ns ±60 mV
load step
VVINBXX stepping 3.3 V <—> 3.8 V, tr= tf= 10
Transient line response µs, ±15 mV
IOUT = 2000 mA DC
DC load each phase 2500
IOUT Output current mA
Six phases combined(5) 15000
Effective capacitance during operation, VOUT =
COUT Output capacitance(6) 0.6 V to 1.67 V, Min value over TA–40°C to 30 50 µF
85°C
Input capacitance on each input Effective capacitance during operation, 2.5 V
CIN 2.5 10 µF
voltage rail(6)(7) VVINBXX 5 V
L Output inductance Effective inductance during operation 0.25 0.47 1 µH
IBALANCE Current balancing accuracy IOUT 1000 mA < 10%
COUT ESR = 10 m
Output voltage ripple PWM
VRIPPLE_PWM PWM mode, IOUT = 200 mA 7 mVPP
mode, One phase active(8) Switching frequency = 4 MHz
COUT ESR = 10 m
Output voltage ripple PFM
VRIPPLE_PFM PFM mode 8 mVPP
mode(8) IOUT = 100 µA
(5) The power switches in the LP8755 are designed to operate continuously with currents up to the switch current limit thresholds. However,
when continuously operating at high current levels there will be significant heat generated within the IC and thus sustained total DC
current which the device can support is typically limited by thermal constraints. Thermal issues will become extremely important when
designing PCB and the thermal environment of the LP8755. PCB with high thermal efficiency is required to ensure the junction
temperature is kept below 125°C. Completing thermal analyses in early stages of the product design process is highly recommended to
predict thermal performance at board level. Under high current load conditions the serial bus master device must monitor the
temperature of the converter using the Thermal warning feature, see Protection Features Characteristics. If the 2nd thermal warning is
triggered at 120°C, the application must quickly decrease the load current to keep the converter within its recommended operating
temperature.
(6) Low-ESR Surface-Mount Ceramic Capacitors (MLCCs) used in setting electrical characteristics. The performance of the LP8755 device
depends greatly on the care taken in designing the Printed Circuit Board (PCB). The use of low inductance and low serial resistance
ceramic capacitors is strongly recommended, while proper grounding is crucial. Attention should be given to decoupling the power
supplies. Decoupling capacitors must be connected close to the IC and between the power and ground pins to support high peak
currents being drawn from System Power Rail during turn-on of the switching MOSFETs. Keep input and output traces as short as
possible, because trace inductance, resistance and capacitance can easily become the performance limiting items.
(7) In addition to these capacitors, at least one higher value capacitor (for example, 22 µF) should be placed close to the power pins. Note
that cores B0-B1 and B3-B4 do have combined power input pins.
(8) Ripple voltage should be measured at COUT electrode on a well-designed PCB, using suggested inductors and capacitors and with a
high-quality scope probe.
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6-Phase Buck System Characteristics (continued)
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP)
values at TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless
otherwise noted).
PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
COUT ESR = 10 m
Output Voltage Ripple Low-
VRIPPLE_LP Low-power PFM mode 8 mVPP
Power PFM mode(8) IOUT = 100 µA
6.8 Protection Features Characteristics
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP) at
TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless otherwise
noted). PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
VOLTAGE MONITORING
Power good threshold for voltage
VPG Power good threshold voltage 90%
decreasing, % of setting, VOUT = 1.1 V
Input overvoltage protection trigger VIN rising. Voltage monitored on VDDA5V
VOVP 5.15 5.3 5.45
point(3)(4) pin V
Input undervoltage lockout (UVLO) VIN falling. Voltage monitored on VDDA5V
VUVLO 2.15 2.25 2.35
turn-on threshold(3) pin
Detected by sensing the voltage on
VSCP Output short-circuit fault threshold 400 mV
converter output with respect to GND.
Triggered by converter start-up, specified by
tMASKSCP SCP masking time 400 µs
design
Triggered by converter start-up, specified by 400 µs
design
Triggered by VSET transition, specified by
design
Slew Rate setting mV/µs
30 50
15 100
tMASKPG Power Good masking time 7.5 200
3.8 400 µs
1.9 800
0.94 1600
0.47 3200
0.23 6400
(1) Junction-to-ambient thermal resistance value given is valid for High-K PCB, and is highly application and board-layout dependent. In
applications where high maximum power dissipation exists, special care must be paid to thermal dissipation issues in board design.
(2) Low-ESR Surface-Mount Ceramic Capacitors (MLCCs) used in setting electrical characteristics. The performance of the LP8755 device
depends greatly on the care taken in designing the Printed Circuit Board (PCB). The use of low inductance and low serial resistance
ceramic capacitors is strongly recommended, while proper grounding is crucial. Attention should be given to decoupling the power
supplies. Decoupling capacitors must be connected close to the IC and between the power and ground pins to support high peak
currents being drawn from System Power Rail during turn-on of the switching MOSFETs. Keep input and output traces as short as
possible, because trace inductance, resistance and capacitance can easily become the performance limiting items.
(3) Undervoltage lockout (UVLO) and overvoltage protection (OVP) circuits shut down the LP8755 when the system input voltage is outside
the desired operating range.
(4) Limits for OVP trigger points apply when VVIOSYS is high. False OVP alarm may occur, if the input voltage rises close to 5 V while
VVIOSYS is low.
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Protection Features Characteristics (continued)
Minimum (MIN) and maximum (MAX) limits apply over the full ambient temperature range –40°C TA85°C; typical (TYP) at
TA= 25°C (unless otherwise noted)(1)(2). VVDDA5V = VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless otherwise
noted). PARAMETER TEST CONDITIONS MIN TYP MAX UNIT
THERMAL SHUTDOWN AND MONITORING
TSHUT Thermal shutdown (TSD) Threshold, Temperature rising 150
Hysteresis 25
Thermal warning Temperature rising, 1st warning, Interrupt 85
only °C
Hysteresis 10
TWARN Thermal warning prior to TSD Temperature rising, 2nd warning, Interrupt 120
and flag set
Hysteresis 10
6.9 I2C Serial Bus Timing Parameters
Serial bus address is selected by the ADDR pin. Connect the pin to GND (addr = 60h), VIOSYS (addr = 61h), SDASYS (addr
= 62h), or SCLSYS (addr = 63h). Both of the serial buses share the same address; that is, if addr = 60h is selected for the
System bus, the Dynamic Voltage Scaling bus will respond to the same address. Start conditions are used to secure the I2C
slave address. During the I2C bus start condition, it is detected whether the ADDR is connected to SDASYS, SCLSYS, GND,
or VIOSYS. The I2C host should allow at least 500 µs before sending data to the LP8755 after the rising edge of the VIOSYS
line.
These specifications are ensured by design. Limits apply over the full ambient temperature range –40°C TA85°C, VVDDA5V
= VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless otherwise noted) (See Figure 1) .
MIN NOM MAX UNIT
DIGITAL TIMING SPECIFICATIONS (SCL, SDA)(1)(2)(3)
Standard mode 100 kHz
Fast mode 400 kHz
fCLK Serial clock frequency High-speed mode, Cb= 100 pF (max) 3.4 MHz
High-speed mode, Cb= 400 pF (max)(4) 1.7 MHz
Standard mode 4.7 µs
Fast mode 1.3
tLOW SCL low time High-speed mode, Cb= 100 pF (max) 160 ns
High-speed mode, Cb= 400 pF (max)(4) 320
Standard mode 4 µs
Fast mode 0.6
tHIGH SCL high time High-speed mode, Cb= 100 pF (max) 60 ns
High-speed mode, Cb= 400 pF (max)(4) 120
Standard mode 250
tSU;DAT Data setup time Fast mode 100 ns
High-speed mode 10
Standard mode 0 3.45 µs
Fast mode 0 0.9
tHD;DAT Data hold time High-speed mode, Cb= 100 pF (max) 0 70 ns
High-speed mode, Cb= 400 pF (max)(4) 0 150
(1) Unless otherwise stated, 'SDA' in this paragraph refers to both of the SDASR and SDASYS signals, and respectively 'SCL' refers to
SCLSR and SCLSYS signals.
(2) Cbrefers to the capacitance of one bus line. Cbis expressed in pF units. The specification table provided applies to both of the
interfaces; DVS and System interface.
(3) The power-on default setting for the system bus and the DVS bus is High-speed-enabled, there is no handshaking required to initiate
high speed.
(4) For bus line loads Cbbetween 100 pF and 400 pF the timing parameters must be linearly interpolated.
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I2C Serial Bus Timing Parameters (continued)
Serial bus address is selected by the ADDR pin. Connect the pin to GND (addr = 60h), VIOSYS (addr = 61h), SDASYS (addr
= 62h), or SCLSYS (addr = 63h). Both of the serial buses share the same address; that is, if addr = 60h is selected for the
System bus, the Dynamic Voltage Scaling bus will respond to the same address. Start conditions are used to secure the I2C
slave address. During the I2C bus start condition, it is detected whether the ADDR is connected to SDASYS, SCLSYS, GND,
or VIOSYS. The I2C host should allow at least 500 µs before sending data to the LP8755 after the rising edge of the VIOSYS
line.
These specifications are ensured by design. Limits apply over the full ambient temperature range –40°C TA85°C, VVDDA5V
= VVINBXX = 3.7 V, VVIOSYS = VNRST = 1.8 V, VOUT = 1.1 V (unless otherwise noted) (See Figure 1) .
MIN NOM MAX UNIT
Standard mode 4.7 µs
Set-up time for a repeated
tSU;STA Fast mode 0.6
start condition High-speed mode 160 ns
Standard mode 4.0 µs
Hold time for a start or a
tHD;STA Fast mode 0.6
repeated start condition High-speed mode 160 ns
Standard mode 4.7
Bus free time between a stop
tBUF µs
and start condition Fast mode 1.3
Standard mode 4.0 µs
Set-up time for a stop
tSU;STO Fast mode 0.6
condition High-speed mode 160 ns
Standard mode 1000 ns
Fast mode 20 300 ns
trDA Rise time of SDA signal High-speed mode, Cb= 100 pF (max) 10 80 ns
High-speed mode, Cb= 400 pF (max)(4) 20 160 ns
Standard mode 300 ns
Fast Mode 6.5 300 ns
tfDA Fall time of SDA signal High-speed mode, Cb= 100 pF (max) 10 80 ns
High-speed mode, Cb= 400 pF (max)(4) 20 160 ns
Standard mode 1000 ns
Fast mode 20 300 ns
trCL Rise time of SCL signal High-speed mode, Cb= 100 pF (max) 10 40 ns
High-speed mode, Cb= 400 pF (max)(4) 20 80 ns
Rise time of SCL signal after High-speed mode, Cb= 100 pF (max) 10 80 ns
trCL1 a repeated start condition and High-speed mode, Cb= 400 pF (max)(4) 20 160 ns
after acknowledge bit Standard mode 300 ns
Fast mode 6.5 300 ns
tfCL Fall time of a SCL signal High-speed mode, Cb= 100 pF (max) 10 40 ns
High-speed mode, Cb= 400 pF (max)(4) 20 80 ns
Capacitive load for each bus
Cb400 pF
line (SCL and SDA) Fast mode 50
Pulse width of spike
tSP ns
suppressed(5) High-speed mode 10
(5) Spike suppression filtering on SCLSYS, SCLSR, SDASYS and SDASR will suppress spikes that are less than the indicated width.
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C011
C012
0
1
2
3
4
5
6
7
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0
PHASES
LOAD CURRENT (A)
300mA
400mA
500mA
600mA
700mA
800mA
900mA
C006
C005
SCL
SDA
tLOW trCL
tHD;DAT
tHIGH
tfCL
tSU;DAT
tSU;STA tSU;STO
START REPEATED
START STOP
tHD;STA
START
tSP
trDA
tBUF
tfDA
tHD;STA
LP8755
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Figure 1. I2C Timing
6.10 Typical Characteristics
Unless otherwise specified: VVDDA5V = VVINBXX = 3.7 V
Figure 2. Phase Adding vs Load Current in Different
ADD_PH_B0 Settings Figure 3. Phase Shedding vs Load Current in Different
SHED_PH_B0 Settings
Figure 4. PFM Mode Current Consumption vs VIN Figure 5. PWM Mode Current Consumption vs VIN
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7 Detailed Description
7.1 Overview
The LP8755 is a high-efficiency, high-performance power supply IC with six step-down DC-DC converter cores. It
delivers 0.6 V to 1.67 V regulated voltage rail from either a single Li-Ion or three cell NiMH/NiCd batteries to
portable devices such as cell phones and PDAs.
There are three modes of operation for the 6-phase converter, depending on the output current required: PWM
(Pulse Width Modulation), PFM (Pulse-Frequency Modulation), and Low-Power PFM. Converter operates in
PWM mode at high load currents of approximately 250 mA or higher, depending on register setting. Lighter
output current loads will cause the converter to automatically switch into PFM or Low-Power PFM mode for
reduced current consumption and a longer battery life. Forced PWM is also available for highest transient
performance.
Under no-load conditions the device can be set to Standby or Shutdown. Shutdown mode turns off the device,
offering the lowest current consumption (ISHDN = 0.1 µA typ.). Additional features include soft-start, undervoltage
lockout, input overvoltage protection, current overload protection, thermal warning, and thermal shutdown.
The modes and features can be programmed via control registers. All the registers can be accessed with both
I2C serial interfaces: System serial interface and Dynamic voltage scaling (DVS) interface. Using DVS interface
for dynamic voltage scaling prevents latencies if System serial interface is busy. Using DVS interface is optional;
System serial interface can also be used for dynamic voltage scaling.
7.1.1 Buck Information
The LP8755 has six integrated high-efficiency buck converter cores. The cores are designed for flexibility; most
of the functions are programmable, thus allowing optimization of the SMPS operation for each application. The
cores are bundled together to establish a multi-phase converter This is shown in Figure 23.
Operating Modes:
OFF: Output is isolated from the input voltage rail in this mode. Output has an optional pulldown resistor.
PWM: Converter operates in buck configuration. Average switching frequency is constant.
PFM: Converter switches only when output voltage decreases below programmed threshold. Inductor current
is discontinuous.
Low-Power PFM: This mode is similar to PFM mode, but used with lower load conditions. In this mode some
of the internal blocks are turned off between the PFM pulses. Load transient response is compromised due to
the wake-up time.
Features:
DVS support; SmartReflex functionality
Automatic mode control based on the loading
Synchronous rectification
Current mode loop with PI compensator
Soft start
Power good flag with maskable interrupt
Overvoltage comparator
Phase control and spread spectrum techniques for reducing EMI
Average output current sensing (for PFM/PWM entry/exit, phase adding/shedding, and load current reporting)
Current balancing between the phases of the converter
Differential voltage sensing
Dynamic phase adding/shedding, each output being phase shifted
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LP8755
SYS IO
Domain
AGND
Thermal
Monitoring
Oscillator
Reference
Voltage
SCLSYS
SDASYS
NRST
INT
INTERNAL
LDO
1 PF
VLDO
Internal
Pull-down
1.1 M:
Logic Control
EPROM
Buck 0 /
Master 0
FBB0+ / B0
SWB0
VIOSYS
NSLP
(chip EN)
SCLSR
SDASR
SR IO
Domain
Voltage
Monitoring
Buck 1
Buck 2
Buck 3
Buck 4
Buck 5
Configurable
Feedback
Amplifiers
POWER
GROUNDS
SWB1
SWB2
SWB3
SWB4
SWB5
FBB0- / B1
FBB2
FBB3+ / B3
FBB3- / B4
FBB5
SYSTEM
POWER
POWER
INPUTS
ADDR
LP8755
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Overview (continued)
Programmability (The following parameters can be programmed via registers):
Output voltage
Forced PWM operation
Switch current limits for high side FET
PWM/PFM mode entry and exit (based on average output current)
Phase adding and shedding levels
Output voltage slew rate
7.2 Functional Block Diagram
7.3 Features Descriptions
7.3.1 Multi-Phase DC-DC Converters
A multi-phase synchronous buck converter offers several advantages over a single power-stage converter. For
application processor power delivery, lower ripple on the input and output currents and faster transient response
to load steps are the most significant advantages. Also, since the load current is evenly shared among multiple
channels, the heat generated is greatly reduced for each channel due to the fact that power loss is proportional
to square of current. Physical size of the output inductor shrinks significantly for the similar reason. Interleaving
switching action of the converters and channels for a typical application (shown in Figure 23) is illustrated in
Figure 7.
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LOAD CURRENT
EFFICIENCY
N=1
1-PHASE
OPERATION
2-PHASE
OPERATION
3-PHASE
OPERATION
4-PHASE
OPERATION
5-PHASE
OPERATION
6-PHASE
OPERATION
BEST EFFICIENCY OBTAINED WITH
N=2
N=3
N=4 N=5
N=6
+
-
FBP
FBN
DIFFERENTIAL TO
SINGLE-ENDED
+
-
+
-POWER
GOOD
LOOP
COMP
RAMP
GENERATOR
PMOS
CURRENT
SENSE
NMOS
CURRENT
SENSE
GATE
CONTROL
IADC
VDAC
ERROR
AMP
GND
NEG
CURRENT
LIMIT
ZERO
CROSS
DETECT
SW
-+
POS
CURRENT
LIMIT
VIN
VOUT
CONTROL
BLOCK
PROGRAMMABLE
PARAMETERS
SLAVE
INTERFACE
VOLTAGE
SETTING
SLEW RATE
CONTROL
SLAVE
PHASE
CONTROL
MASTER
INTERFACE
LP8755
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Features Descriptions (continued)
Figure 6. Detailed Block Diagram Showing One Buck Core
7.3.1.1 Multi-Phase Operation and Phase-Shedding
Under heavy load conditions, the 6-phase converter switches each channel 60° apart. As a result, the 6-phase
converter has an effective ripple frequency six times greater than the switching frequency of any one phase.
However, the parallel operation decreases the efficiency at light load conditions. In order to overcome this
operational inefficiency, the LP8755 changes the number of active phases to optimize efficiency for the variations
of the load. This is called phase-shedding. The concept is illustrated in Figure 7.
Figure 7. Multi-phase Buck Converter Efficiency vs Number of Phases; All Converters in PWM Mode (6)
(6) Graph is not to scale and is for illustrative purposes only.
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0 60 120 180 240 300 360 420
0 60 120 180 240 300 360 420
PHASE, DEGREES
SWITCHING CYCLE 360°
IL_TOT
IL0
IL1
IL2
IL4
IL5
IL3
PWM1
PWM2
PWM3
PWM4
PWM0
PWM5
LP8755
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Features Descriptions (continued)
Figure 8. PWM Timings and Inductor Current Waveforms (7)
(7) Graph is not to scale and is for illustrative purposes only.
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Features Descriptions (continued)
7.3.1.2 Transitions Between Low-Power PFM, PFM, and PWM Modes
Normal PWM-mode operation with phase-shedding can optimize efficiency at mid-to-full load, but this is usually
at the expense of light-load efficiency. The LP8755 converter operates in PWM mode at a load current of 100 to
375 mA or higher; this mode transition trip-point is set by register. Lighter load current causes the device to
automatically switch into PFM mode for reduced current consumption. By combining PFM and PWM modes in
the same regulator and providing automatic switching, high efficiency can be achieved over a wide output load
current range.
Efficiency is further enhanced when the converter enters Low-Power PFM mode. The LP8755 includes Low-
Power mode function for low-current consumption. In this mode most of the internal blocks are disabled between
the inductor current ramp up and ramp down phases to reduce the operating current. However, as a result, the
transient performance of the converter is compromised. The Low-Power mode can be enabled by control register
setting. Also, the application processor or the PMIC may provide an HW signal (NSLP) to the LP8755 input to
indicate when the processor has entered a low-power state. When the signal is asserted, the LP8755 Low-Power
PFM function will be enabled, and the LP8755 will run with a reduced input current. The right timing of the NSLP
signal from the system is important for best load-transient performance. The NSLP signal should be asserted
only when load current is stable and below 30 mA. Before the load current increases above 30 mA, the NSLP
signal should be de-asserted 100 µs (minimum) prior to a load step to prepare the converter for the higher load
current.
7.3.1.3 Buck Converter Load Current
The buck load current can be monitored via I2C registers. Current of different buck converter cores or the total
load current of the master can be selected from register 0x21 (see SEL_I_LOAD). A write to this selection
register starts a current measurement sequence. The measurement sequence is a minimum of 50 µs long. When
a measurement sequence starts, the FLAGS_1.I_LOAD_READY bit in register 0x0E is set to '0'. After the
measurement sequence is finished, the FLAGS_1.I_LOAD_READY bit is set to '1'. (Note that by default this bit is
'0'.) The measurement result can be read from registers 0x22 (LOAD_CURR.BUCK_LOAD_CURR[7:0]) and
0x21 (SEL_I_LOAD.BUCK_LOAD_CURR[10:8]). The measurement result [10:0] LSB is 10 mA, and the
maximum value of the measurement is 20 A. The LP8755 can be configured to give out an interrupt after the
load current measurement sequence is finished. Load current measurement interrupt can be masked with
INT_MASKS_2.MASK_I_LOAD_READY bit.
7.3.1.4 Spread Spectrum Mode
Systems with periodic switching signals may generate a large amount of switching noise in a set of narrowband
frequencies (the switching frequency and its harmonics). The usual solution to reduce noise coupling is to add
EMI-filters and shields to the boards. The LP8755's register-selectable spread spectrum mode minimizes the
need for output filters, ferrite beads, or chokes. In spread spectrum mode, the switching frequency varies
randomly around the center frequency, reducing the EMI emissions radiated by the converter, associated passive
components, and PCB traces. See Figure 9.
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VIOSYS
VINBXX
LDO
(internal) t1
NRST t2
t0
tI2CT LP8755 receiving/sending data across the system I2C bus.
POWER SPECTRUM IS
SPREAD AND LOWERED
FREQUENCY
RADIADED ENERGY
LP8755
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Features Descriptions (continued)
Where a fixed-frequency converter exhibits large amounts of spectral energy at the switching frequency, the spread
spectrum architecture of the LP8755 spreads that energy over a large bandwidth.
Figure 9. Spread Spectrum Modulation
7.3.2 Power-Up and Output Voltage Sequencing
The power-up sequence for the LP8755 is as follows:
VVINBXX and VVDDA5V reach min recommended levels.
VVIOSYS set high. Enables the system I/O interface. For power-on-reset (POR), the I2C host should allow at
least 500 µs before sending data to the LP8755 after the rising edge of the VIOSYS line.
VLDO voltage is raising. The LDO voltage is generated internally. The internal POR signal is activated.
Internal POR deasserted, OTP read.
Device enters standby mode.
DC-DC enable, output voltage, voltage slew rate programmed over I2C as needed by the application.
NRST set high.
Figure 10. Timing Diagram for the Power-Up Sequence
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1
NRST
VVIOSYS
VVDDA5V
NRST
2
VVIOSYS
VVDDA5V
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Features Descriptions (continued)
Table 1. Power-Up Sequence
PARAMETER CONDITION(1) MIN TYP MAX UNIT
t0VVDDA5V to VVIOSYS assertion 0 µs
t1LDOON Delay Time CLDO = 1 µF <100 150 µs
t2LDOON to NRST HIGH 0 µs
tI2CT Device ready for I2C data transfer 500 µs
(1) These specification table entries are specified by design. The power input lines VVINBXX, VVDDA5V and VVIOSYS must be stable before the
NRST line goes High. Also, the VLDO line must be stable 1.8 V before the NRST line goes High.
7.3.3 Device Reset Scenarios
There are three reset methods implemented on the LP8755:
Software reset
Hardware reset
Power-on reset (POR)
An SW-reset occurs when the RESET.SW_RESET bit is written first with 1, followed by 0 right after that. This
event resets the control registers shown in Table 2 to the default values. The temperature, power good, and
other faults are persistent over the SW reset to allow for the system to identify to cause of the failure.
An internal power-on reset (POR) occurs when the supply voltage (VVDDA5V) transitions above the POR threshold
or VVIOSYS is toggled low/high. Each of the registers contain a factory-defined value upon POR, and this data
remains there until any of the following occurs:
Device sets a Flag bit, causing the Status register to be updated. The other registers remain untouched.
A different data word is written to a writable register.
The internal registers will lose their contents if the supply voltage (VVDDA5V) goes below 1 V (typ.).
An NRST high-to-low transition initiates the hardware reset. This event resets the control registers shown in
Table 2 to the default values.
Under OVP, UVLO, TSD, or VVIOSYS low (while NRST still high) conditions, a Fast Power-Down is launched.
Normal Power-Down Sequence Follows This Event
(Marked as '1') Fast Power-Down Follows This Event
Figure 11. The External Power Control System De- Figure 12. NRST Stays HIGH While VVIOSYS
asserts NRST Transition from HIGH to LOW Happens (Marked as
'2')
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~2 PsTime
IInductor
0
HW RST by NRST
OTP_MEM_READ
SW RST by I2C
OTP_MEM_READ
tRST1 tRST2
tRST2
LP8755
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Inductor Current Dropping to Zero in ~2 µs (All
Converters, All Phases)
Figure 13. Fast Power-Down Figure 14. Reset Timings
PARAMETER LIMIT
tRST1 NRST active low pulse width 1 µs min + value on DELAY register.
tRST2 NRST inactive or I2C reset 25 µs max
event to MEMORY READ end
Table 2. Hardware Reset, Power-On Reset (POR) and Software Reset: Registers After Reset
SOFTWARE RESET HARDWARE RESET POWER-ON RESET
HEX ADDRESS REGISTER I2C RESET NRST LOW (1) VVIOSYS LOW
0x00 VSET_B0 All bits retained All bits retained All bits cleared
0x06 FPWM All bits cleared All bits cleared All bits cleared
0x07 BUCK0_CTRL All bits cleared All bits cleared All bits cleared
0x0D FLAGS_0 All bits retained All bits retained All bits cleared
0x0E FLAGS_1 All bits retained All bits retained All bits cleared
0x0F INT_MASK0 All bits cleared All bits cleared All bits cleared
0x10 GENERAL All bits cleared All bits cleared All bits cleared
0x11 RESET N/A All bits cleared All bits cleared
0x12 DELAY_BUCK0 All bits cleared All bits cleared All bits cleared
0x18 CHIP_ID Read Only
0x19 PFM_LEV_B0 All bits cleared All bits cleared All bits cleared
0x1F PHASE_LEV_B0 All bits cleared All bits cleared All bits cleared
0x21 SEL_I_LOAD All bits retained All bits retained All bits cleared
0x22 LOAD_CURR Read Only
0x2E INT_MASK_2 All bits cleared All bits cleared All bits cleared
(1) Reset is falling-edge sensitive and it will take effect upon complete of the power-down sequence. The registers can be updated by I2C
writing when NRST is low.
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Time
Voltage
VOUT
tMASK, RAMP
tMASK, START
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7.3.4 Diagnosis and Protection Features
The LP8755 is capable of providing two levels of protection features: warnings for diagnosis and faults which are
causing the converters to shut down. When the device detects warning or fault conditions, the LP8755 sets the
flag bits indicating which fault or warning conditions have occurred; the INT pin will be pulled low. INT will be
released again after a clear of flags is complete. The flag bits are persistent over reset to allow for the system to
identify what was causing the interrupt and/or converter shutdown.
Also, the LP8755 has a soft-start circuit that limits in-rush current during start-up. The output voltage increase
rate is 30 mV/µs (default) during soft-start.
Table 3. Summary of Exceptions and Interrupt Signals
EVENT REGISTER.BIT INTERRUPT SIGNAL INT MASK AVAILABLE?
PRODUCED?
SCP triggered FLAGS_1.SCP Yes Yes
Not PowerGood FLAGS_0.nPG Yes Yes
TEMP status change FLAGS_0.TEMP[1:0] On any temperature change Yes
except for the case when
TEMP[1:0] = 0b11
Thermal warning FLAGS_1.T_WARNING Yes Yes
Thermal shutdown FLAGS_1.THSD Yes No
OVP triggered FLAGS_1.OVP Yes Yes
Load current measurement FLAGS_1.I_LOAD_READY Yes Yes
ready
UVLO triggered FLAGS_1.UVLO Yes Yes
7.3.4.1 Warnings for Diagnosis (No Power Down)
7.3.4.1.1 Short-Circuit Protection (SCP)
A short-circuit protection feature allows the LP8755 to protect itself and external components during overload
conditions. The output short-circuit fault threshold is 400 mV (typ.) .
7.3.4.1.2 Power Good Monitoring
When the converter's feedback-pin voltage falls lower than 90% (typ.) of the set voltage, the FLAGS_0.nPG flag
is set. To prevent a false alarm, the power good circuit is masked during converter start-up and voltage
transitions. The duration of the power good mask is set to 400 µs for converter start-up. For voltage ramps the
masking time is extended by an internal logic circuit up to 6.4 ms. (See Protection Features Characteristics.)
Masking time for start-up is constant 400 µs (typ.). Masking time for voltage transitions depends on the selected ramp
rates.
Figure 15. Power Good Masking Principle
7.3.4.1.3 Thermal Warnings
Prior to the thermal shutdown, thermal warnings are set. The first warning is set at 85°C (INT pin low), and the
second at 120°C (INT pin pulled low and FLAGS_1.T_WARNING flag set). If the chip temperature crosses any of
the thresholds of 85°C, 120°C, or 150°C (see FLAGS_0 register) the INT pin will be triggered. INT will be cleared
upon read of FLAGS_0.TEMP[1:0] bits except if FLAGS_0.TEMP [1:0] = 0b11, which is a thermal fault event.
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7.3.4.2 Faults (Fault State and Fast Power Down)
7.3.4.2.1 Undervoltage Lockout (UVLO)
When the input voltage falls below VUVLO (typ. 2.25 V) at the VDDA5V pin, the LP8755 indicates a fault by
activating the FLAGS_1.UVLO flag. The buck converter shut down without a power-down sequence(Fast Power-
Down). The flag will remain active until the input voltage is raised above the UVLO threshold. If the flag is
cleared while the fault persists, the flag is immediately re-asserted, and interrupt remains active.
7.3.4.2.2 Overvoltage Protection (OVP)
When an input voltage greater than VOVP (typ. 5.3 V) is detected at the VDDA5V pin, the LP8755 indicates a fault
by activating the FLAGS_1.OVP flag. The buck converter shut down without power-down sequence (Fast Power-
Down). The flag will remain active until the input voltage is below the OVP threshold. If the flag is cleared while
the fault persists, the flag is immediately re-asserted and interrupt remains active.
7.3.4.2.3 Thermal Shutdown (THSD)
The LP8755 has a thermal overload protection function that operates to protect itself from short-term misuse and
overload conditions. When the junction temperature exceeds around 150°C, the device enters shutdown via fault-
state. INT will be cleared upon write of the FLAGS_1.THSD flag even when thermal shutdown is active. This
allows automatic recovery when temperature decreases below thermal shutdown level. See Figure 16 for
LP8755 thermal diagnosis and protection features.
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Yes
INT Requested
If THSD low then enable
power outputs
TEMP[1:0] = 0b11
Power Outputs Disabled
TEMP[1:0] = 0b10
TEMP[1:0] = 0b01
TEMP[1:0] = 0b00
Tj > 85°C
Yes
INT Requested
No
Tj < 75°C
No
Tj > 120°C
No
Tj > 150°C
Tj < 110°C
No
Tj < 125°C No
Read FLAGS_0
INT Released
Read FLAGS_0
INT Released
Read FLAGS_0
Yes
INT Requested
T_WARNING Asserted
Yes
INT Requested
THSD Asserted
Yes
INT Requested
Clear THSD
E\ZULWLQJ¶0'
Read FLAGS_0
INT Released
THSD De-asserted
Clear T_WARNING
E\ZULWLQJ¶0'
INT by T_WARNING
released
Yes
INT Requested
INT by change in
TEMP released
No
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Note that INT is asserted whenever any of the thermal thresholds is crossed, if unmasked. Note also the 10°C
Hysteresis on the TJThresholds.
Figure 16. Thermal Warnings and Thermal Shutdown Flow
7.4 Device Functional Modes
SHUTDOWN: All switch, reference, control and bias circuitry of the LP8755 are turned off. The main battery
supply voltage is high enough to start the buck power-up sequence but VVIOSYS and NRST are
LOW.
STANDBY: Setting VVIOSYS HIGH enables standby-operation. All registers can be read or written by the system
master via the system serial interface. Recovery from UVLO, TSD, or OVP event also leads to
standby.
ACTIVE: Regulated DC-DC converters are on or can be enabled with full current capability. In this mode, all
features and control registers are available via the system serial bus and via SmartReflex interface.
LOW-POWER: At light loads (less than approximately 30 mA), and when the load does not require highest level
of transient performance, the device enters automatically Low-Power mode. In this mode the part
operates at low IQ. Conditions entering and exiting Low-Power mode are shown in Figure 17.
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SHUTDOWN
STANDBY
ACTIVE
ACTIVE
LOW POWER
VVIOSYS
LOW
VVIOSYS
HIGH
NRST HIGH
NRST LOW
or
I2C RESET
**) LOW LOAD CURRENT AND ALL
THE FOLLOWING CONDITIONS
*) HIGH LOAD CURRENT OR ANY OF
THE FOLLOWING CONDITIONS:
**
NSLP (pin) LOW
LP_B0 (bit) µ1
µ1
µ0
LP_EN (bit)
FPWM_B0 (bit)
NSLP (pin) HIGH
LP_B0 (bit) µ0
µ0
µ1
LP_EN (bit)
FPWM_B0 (bit)
READ
OTP
FAULT CONDITION
DETECTED
REG
RESET ***
THERMAL
SHUTDOWN
or
UVLO/OVP
RELEASED
and
FLAG(s) CLEARED
FROM ANY STATE
EXCEPT SHUTDOWN
***) 6((´5(6(76&(1$5,26´)25
DETAILS
I2C RESET
*
FROM ANY
STATE
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Device Functional Modes (continued)
Figure 17. Device Operation Modes
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SDA
Start Condition Stop Condition
SCL S P
SCL
SDA
data
change
allowed
data
valid data
change
allowed
data
valid data
change
allowed
LP8755
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7.5 Programming
7.5.1 I2C-Compatible Interface
The I2C-compatible synchronous serial interface provides access to the programmable functions and registers on
the device. This protocol uses a two-wire interface for bidirectional communications between the IC's connected
to the bus. The two interface lines are the Serial Data Line (SDA), and the Serial Clock Line (SCL). Every device
on the bus is assigned a unique address and acts as either a Master or a Slave depending on whether it
generates or receives the serial clock SCL. The SCL and SDA lines should each have a pullup resistor placed
somewhere on the line and remain HIGH even when the bus is idle. Note: CLK pin is not used for serial bus data
transfer. There are two buses implemented: the System I2C bus and the SmartReflex bus. In the following
paragraphs, SCL refers to both SCLSYS and SCLSR, and SDA refers to SDASYS and SDASR. The LP8755
supports standard mode (100 kHz), fast mode (400 kHz) and high-speed mode (3.4 MHz).
7.5.1.1 Data Validity
The data on SDA line must be stable during the HIGH period of the clock signal (SCL). In other words, state of
the data line can only be changed when clock signal is LOW.
Figure 18. Data Validity Diagram
7.5.1.2 Start and Stop Conditions
The LP8755 is controlled via an I2C-compatible interface. START and STOP conditions classify the beginning
and end of the I2C session. A START condition is defined as SDA transitions from HIGH to LOW while SCL is
HIGH. A STOP condition is defined as SDA transition from LOW to HIGH while SCL is HIGH. The I2C master
always generates the START and STOP conditions.
Figure 19. Start and Stop Sequences
The I2C bus is considered busy after a START condition and free after a STOP condition. During data
transmission the I2C master can generate repeated START conditions. A START and a repeated START
condition are equivalent function-wise. The data on SDA must be stable during the HIGH period of the clock
signal (SCL). In other words, the state of SDA can only be changed when SCL is LOW. Figure 1 shows the SDA
and SCL signal timing for the I2C-Compatible Bus. See the I2C Serial Bus Timing Parameters for timing values.
7.5.1.3 Transferring Data
Every byte put on the SDA line must be eight bits long, with the most significant bit (MSB) being transferred first.
Each byte of data has to be followed by an acknowledge bit. The acknowledge related clock pulse is generated
by the master. The master releases the SDA line (HIGH) during the acknowledge clock pulse. The LP8755 pulls
down the SDA line during the 9th clock pulse, signifying an acknowledge. The LP8755 generates an
acknowledge after each byte has been received.
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R/W
Bit 0
0
Bit 1
0
Bit 2
0
Bit 3
0
Bit 4
0
Bit 5
1
Bit 7 1
Bit 6
MSB LSB
I2C Slave Address (chip address)
ack from slave
start MSB Chip Addr LSB
SCL
ack from slave
w MSB Register Addr LSB rs r MSB Data LSB stop
ack from slave nack from masterrepeated start data from slave
SDA
start id =60h w ack address = 3Fh ack rs r ack address 3Fh data nack stop
MSB Chip Address LSB
id = 60h
start MSB Chip Addr LSB w ack MSB Register Addr LSB ack MSB Data LSB ack stop
ack from slave ack from slave ack from slave
SCL
SDA
start id = 60h w ack addr = 40h ack ackaddress 40h data stop
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Programming (continued)
There is one exception to the “acknowledge after every byte” rule. When the master is the receiver, it must
indicate to the transmitter an end of data by not-acknowledging (“negative acknowledge”) the last byte clocked
out of the slave. This “negative acknowledge” still includes the acknowledge clock pulse (generated by the
master), but the SDA line is not pulled down.
After the START condition, the bus master sends a chip address. This address is seven bits long followed by an
eighth bit which is a data direction bit (READ or WRITE). For the eighth bit, a “0” indicates a WRITE and a “1”
indicates a READ. The second byte selects the register to which the data will be written. The third byte contains
data to write to the selected register.
Figure 20. Write Cycle (w = write; SDA = '0'), id = device address = 60Hex for LP8755.
When READ function is to be accomplished, a WRITE function must precede the READ function as shown above.
Figure 21. Read Cycle ( r = read; SDA = '1'), id = device address = 60Hex for LP8755.
7.5.1.4 I2C-Compatible Chip Address
The device address for the LP8755 is 0x60 (ADDR pin tied to the GND). After the START condition, the I2C
master sends the 7-bit address followed by an eighth bit, read or write (R/W). R/W = 0 indicates a WRITE and
R/W = 1 indicates a READ. The second byte following the device address selects the register address to which
the data will be written. The third byte contains the data for the selected register.
Here device address is 1100000Bin = 60 Hex.
Figure 22. Device Address
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Programming (continued)
7.5.1.5 Auto-Increment Feature
The auto-increment feature allows writing several consecutive registers within one transmission. Every time an 8-
bit word is sent to the LP8755, the internal address index counter will be incremented by one, and the next
register will be written. Table 4 shows writing sequence to two consecutive registers. Note: the auto-increment
feature does not work for read.
Table 4. Auto-Increment Example
Master Start Device Write Register Data Data Stop
Action Address Address
= 60H
LP8755 ACK ACK ACK ACK
Action
7.6 Register Maps
7.6.1 Register Descriptions
The LP8755 is controlled by a set of registers through the system serial interface port or through the
SmartReflex-compatible interface. Table 5 lists device registers, their addresses and their abbreviations. A more
detailed description is given in the sections VSET_B0 to INT_MASK_2.
Many registers contain bits, that are reserved for future use. When writing to a register, any reserved bits should
not be changed.
Table 5. Register Descriptions
Read /
Addr Register D7 D6 D5 D4 D3 D2 D1 D0
Write
EN_DIS_B
0x00 VSET_B0 R/W VSET_B0[6:0]
0
0x06 FPWM R/W Reserved FPWM_B0
0x07 BUCK0_CTRL R/W OC_LEV_B0[1:0] LP_B0 RDIS_B0 Reserved RAMP_B0[2:0]
0x0D FLAGS_0 R/W Reserved nPG_B0 TEMP[1:0]
I_LOAD_REA T_WARNIN
0x0E FLAGS_1 R/W Reserved UVLO THSD OVP SCP
DY G
MASK_nPG
0x0F INT_MASK_0 R/W Reserved MASK_OVP MASK_SCP
_B0
0x10 GENERAL R/W Reserved EN_SS Reserved DIS_DIF_B0 Reserved SLP_POL LP_EN
0x11 RESET R/W Reserved SW_RESET
0x12 DELAY_BUCK0 R/W DELAY_B0[7:0]
0x18 CHIP_ID R VENDOR[1:0] ALL_LAYER[1:0] METAL_LAYER[3:0]
0x19 PFM_LEV_B0 R/W Reserved PFM_ENTRY_B0[2:0] Reserved PFM_EXIT_B0[2:0]
0x1F PHASE_LEV_B0 R/W Reserved ADD_PH_B0[2:0] Reserved SHED_PH_B0[2:0]
0x21 SEL_I_LOAD R/W Reserved BUCK_LOAD_CURR[10:8] Reserved LOAD_CURRENT_SOURCE[2:0]
0x22 LOAD_CURR R BUCK_LOAD_CURR[7:0]
MASK_ILOA MASK_UVL MASK_TWA MASK_TEM
0x2E INT_MASK_2 R/W Reserved D_READY O RNING P
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7.6.2 VSET_B0
Address: 0x00
D7 D6 D5 D4 D3 D2 D1 D0
EN_DIS_B0 VSET_B0[6:0]
Bits Field Type Default Description
7 EN_DIS_B0 R/W 1 DC-DC converter Buck0 Enable/Disable. The Enable of the master Buck0 controls the
operation of the slave bucks.
0 = Converter disabled
1 = Converter enabled
Note: When a disable request is received the converter is disabled immediately.
6:0 VSET_B0[6:0] R/W 011 1100 Sets the output voltage.
Defined by:
VOUT = 0.5 V + 10 mV * VSET_B0
VOUT range = 0.6 V to 1.67 V
NOTE: Do not use VSET_B0 values < 0001010 (10 dec) = 0.6 V.
NOTE: Register settings starting from 1110110 up to 1111111 are clamped to 1.67 V.
7.6.3 FPWM
Address: 0x06
D7 D6 D5 D4 D3 D2 D1 D0
Reserved FPWM_B0
Bits Field Type Default Description
7:1 Reserved R/W 001 1111
0 FPWM_B0 R/W 1 Forced PWM mode of operation, Buck regulator 0 (Master). The setting of the master
controls the operation of the slave bucks.
0 = PWM, PFM or Low-Power PFM operation mode.
1 = This will force the master converter and the slaves to operate always in the PWM
mode.
7.6.4 BUCK0_CTRL
Address: 0x07
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B0[1:0] LP_B0 RDIS_B0 Reserved RAMP_B0[2:0]
Bits Field Type Default Description
7:6 OC_LEV_B0[1:0] R/W 11 Inductor positive current limit on Buck 0. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5 LP_B0 R/W 0 Allows converter to enter into Low-Power PFM mode.
1 = Entering to Low-Power PFM mode is allowed.
0 = Entering to Low-Power PFM more is not allowed.
4 RDIS_B0 R/W 1 Enables the output discharge resistors when the VOUT supply has been disabled.
1 = Enable pull-down
0 = Disable pull-down
3 Reserved R/W 0
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Bits Field Type Default Description
2:0 RAMP_B0[2:0] R/W 001 This set the output voltage change ramp as follows:
000 = 30 mV/µs
001 = 15 mV/µs
010 = 7.5 mV/µs
011 = 3.8 mV/µs
100 = 1.9 mV/µs
101 = 0.94 mV/µs
110 = 0.47 mV/µs
111 = 0.23 mV/µs
7.6.5 BUCK1_CTRL
Address: 0x08
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B1[1:0] Reserved
Bits Field Type Default Description
7:6 OC_LEV_B1[1:0] R/W 11 Inductor positive current limit on Buck 1. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5:0 Reserved R/W 01 0001
7.6.6 BUCK2_CTRL
Address: 0x09
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B2[1:0] Reserved
Bits Field Type Default Description
7:6 OC_LEV_B2[1:0] R/W 11 Inductor positive current limit on Buck 2. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5:0 Reserved R/W 01 0001
7.6.7 BUCK3_CTRL
Address: 0x0A
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B3[1:0] Reserved
Bits Field Type Default Description
7:6 OC_LEV_B3[1:0] R/W 11 Inductor positive current limit on Buck 3. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5:0 Reserved R/W 01 0001
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7.6.8 BUCK4_CTRL
Address: 0x0B
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B4[1:0] Reserved
Bits Field Type Default Description
7:6 OC_LEV_B4[1:0] R/W 11 Inductor positive current limit on Buck 4. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5:0 Reserved R/W 01 0001
7.6.9 BUCK5_CTRL
Address: 0x0C
D7 D6 D5 D4 D3 D2 D1 D0
OC_LEV_B5[1:0] Reserved
Bits Field Type Default Description
7:6 OC_LEV_B5[1:0] R/W 11 Inductor positive current limit on Buck 5. Note that OC_LEV_B0...B5 should have the
same value.
00 = 1.5 A
01 = 2.0 A
10 = 2.5 A
11 = 3.0 A
5:0 Reserved R/W 01 0001
7.6.10 FLAGS_0
Address: 0x0D
D7 D6 D5 D4 D3 D2 D1 D0
Reserved nPG_B0 TEMP[1:0]
Bits Field Type Default Description
7:3 Reserved R/W X XXXX
2 nPG_B0 R/W 0 Flag Bit (1)
Power good fault flag for VOUT rail
1 = Power fault detected
0 = Power good
1:0 TEMP[1:0] R 00 indicates the die temperature as follows:
00: die temperature lower than 85ºC
01: 85ºC die temperature < 120ºC
10: 120ºC die temperature < 150ºC
11: die temperature 150ºC or higher
(1) The flag bit can be cleared only by writing a zero to the associated register bit or power cycling the device (VVIOSYS to LOW). Reading or
RESET does not clear the flag bits. After clearing, the nPG fault flag will be raised again '1' if the fault condition persists. Any unmasked
flag bit High will cause the interrupt to be asserted on the INT pin. The INT pin will be pulled Low until all the unmasked flags are clear
again.
7.6.11 FLAGS_1
Address: 0x0E
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D7 D6 D5 D4 D3 D2 D1 D0
Reserved I_LOAD_READ UVLO T_WARNING THSD OVP SCP
Y
Bits Field Type Default Description
7:6 Reserved R/W 00
5 I_LOAD_READY R/W 0 Flag Bit(1)
1 = Buck load current measurement data ready
0 = Buck load current measurement data not ready
4 UVLO R/W 0 Flag Bit (1)
1= Input undervoltage lockout (UVLO): Input voltage sagged below UVLO threshold.
0 = No UVLO
3 T_WARNING R/W 0 Flag Bit (1)
1= Thermal warning: The IC temperature exceeds 120°C, in advance of the thermal
shutdown protection.
0 = No thermal warning
2 THSD R/W 0 Flag Bit (1)
1 = Thermal shutdown event detected
0 = No thermal shutdown
1 OVP R/W 0 Flag Bit (1)
1= Indicates overvoltage protection (OVP) circuit activation.
0 = No OVP event. The OVP circuitry monitors VDDA5V power input.
0 SCP R/W 0 Flag Bit (1)
1= Indicates short-circuit protection (SCP) circuit activation. The bit is activated when a
short-circuit condition is detectedon output rail.
0 = No SCP event
(1) The flag bit(s) can be cleared only by writing a zero to the associated register bit(s) or power cycling the device (VVIOSYS to LOW).
Reading or RESET does not clear the flag bits. After clearing, the OVP, SCP fault flag(s) will be raised again '1' if the fault condition
persists. The THSD flag will remain '0' after clear, even though the fault condition persists. Any unmasked flag bit High will cause the
interrupt to be asserted on the INT pin. The INT pin will be pulled Low until all the unmasked flags are clear again.
7.6.12 INT_MASK_0
Address: 0x0F
D7 D6 D5 D4 D3 D2 D1 D0
Reserved MASK_nPG_B MASK_OVP MASK_SCP
0
Bits Field Type Default Description
7:3 Reserved R/W 1 1111
2 MASK_nPG_B0 R/W 0 Interrupt mask for power good fault flag
1 = nPG does not set interrupt.
0 = nPG sets interrupt, when triggered.
1 MASK_OVP R/W 0 Interrupt mask for Overvoltage Protection (OVP) fault flag
1 = OVP does not set interrupt.
0 = OVP sets interrupt, when triggered.
0 MASK_SCP R/W 0 Interrupt mask for short-circuit protection SCP fault flag
1 = SCP does not set interrupt.
0 = SCP sets interrupt, when triggered.
7.6.13 GENERAL
Address: 0x10
D7 D6 D5 D4 D3 D2 D1 D0
Reserved EN_SS Reserved DIS_DIF_B0 SLP_POL LP_EN
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Bits Field Type Default Description
7:6 Reserved R/W 00
5 EN_SS R/W 0 Spread Spectrum
1 = Spread Spectrum enabled
0 = Spread Spectrum disabled
4 Reserved R/W 0
3 DIS_DIF_B0 R/W 0 Disable Differential-to-single-ended amplifier
1 = Differential amplifier disabled
0 = Differential amplifier enabled
2 R/W 0
1 SLP_POL R/W 0 Sets the polarity of the NSLP pin
1 = NSLP is active high
0 = NSLP is active low
0 LP_EN R/W 1 1 = allows Low-Power PFM mode. In order to reduce power consumption under low
load conditions, the unit will automatically switch off unused internal blocks.
0 = Low-Power mode not allowed
7.6.14 RESET
Address: 0x11
D7 D6 D5 D4 D3 D2 D1 D0
Reserved SW_RESET
Bits Field Type Default Description
7:1 Reserved R/W 000 0000
0 SW_RESET R/W 0 Writing this bit with '1' and '0', in this order, will reset the registers to the default values.
If NRST is still kept HIGH, the converter output(s) will be regulated to the programmed
register values. If a full POR reset is required VVIOSYS must be pulled low. The fault
flags are persistent over SW-reset.
7.6.15 DELAY_BUCK0
Address: 0x12
D7 D6 D5 D4 D3 D2 D1 D0
DELAY_B0
Bits Field Type Default Description
7:0 DELAY_B0 R/W 0000 0000 Master delay
Sets the delay time from when NRST is asserted to when the VOUT rail is enabled.
Sets the delay time from when NRST is de-asserted to when the VOUT rail is disabled.
DELAY = DELAY_B0 * 100 µs
If DELAY_B0 = FFh, supply is never enabled. (1)
(1) If this register is set to FFh when the converter is already started, it will cause an immediate power down of the converter.
7.6.16 CHIP_ID
Address: 0x18
D7 D6 D5 D4 D3 D2 D1 D0
DEVICE OTP_REV DIE_REV
Bits Field Type Default Description
7 DEVICE R 1 DEVICE
Contains Device ID
6:2 OTP_REV R 0 0001 OTP_REV
Contains OTP Version ID
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Bits Field Type Default Description
1:0 DIE_REV R 00 DIE_REV
Contains Revision ID
7.6.17 PFM_LEV_B0
Address: 0x19
D7 D6 D5 D4 D3 D2 D1 D0
Reserved PFM_ENTRY_B0[2:0] Reserved PFM_EXIT_B0[2:0]
Bits Field Type Default Description
7 Reserved R/W 0
6:4 PFM_ENTRY_B0 R/W PFM_ENTRY_B0 (1)
Sets the target PFM entry level for Buck 0. The final PWM-to-PFM switchover current
varies slightly and is dependant on the output voltage, input voltage and the inductor
current level.
000 = 50 mA
001 = 75 mA
010 = 100 mA
011 = 125 mA
100 = 175 mA
101 = 225 mA
110 = 275 mA
111 = 325 mA
3 Reserved R/W 0
2:0 PFM_EXIT_B0 R/W 101 PFM_EXIT_B0 (1)
Sets the target PFM exit level for Buck 0. The final PFM-to-PWM switchover current
varies slightly and is dependant on the output voltage, input voltage and the inductor
current level.
000 = 100 mA
001 = 125 mA
010 = 150 mA
011 = 175 mA
100 = 225 mA
101 = 275 mA
110 = 325 mA
111 = 375 mA
(1) For proper operation, the PFM exit current level should be at least 50 mA higher than the PFM entry current level.
7.6.18 PHASE_LEV_B0
Address: 0x1F
D7 D6 D5 D4 D3 D2 D1 D0
Reserved ADD_PH_B0[2:0] Reserved SHED_PH_B0[2:0]
Bits Field Type Default Description
7 Reserved R/W 0
6:4 ADD_PH_B0 R/W 100 ADD_PH_B0(1)
Sets the level on which a phase is added.
000 = 0.3 A * No. of Active Phases
001 = 0.4 A * No. of Active Phases
010 = 0.5 A * No. of Active Phases
011 = 0.6 A * No. of Active Phases
100 = 0.7 A * No. of Active Phases
101 = 0.8 A * No. of Active Phases
110 = 0.9 A * No. of Active Phases
111 = 1.0 A * No. of Active Phases
3 Reserved R/W 0
(1) ADD_PH_B0 and SHED_PH_B0 values must be chosen so that the resulting hysteresis is a minimum of 100 mA and ADD_PH_B0 >
SHED_PH_B0.
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Bits Field Type Default Description
2:0 SHED_PH_B0 R/W 010 SHED_PH_B0(1)
Sets the level of phase shedding.
000 = 0.3 A * No. of Active Phases
001 = 0.4 A * No. of Active Phases
010 = 0.5 A * No. of Active Phases
011 = 0.6 A * No. of Active Phases
100 = 0.7 A * No. of Active Phases
101 = 0.8 A * No. of Active Phases
110 = 0.9 A * No. of Active Phases
111 = 1.0 A * No. of Active Phases
7.6.19 SEL_I_LOAD
Address: 0x21
D7 D6 D5 D4 D3 D2 D1 D0
Reserved BUCK_LOAD_CURR[10:8] Reserved LOAD_CURRENT_SOURCE[2:0]
Bits Field Type Default Description
7 Reserved R/W 0
6:4 BUCK_LOAD_ R 000 BUCK_LOAD_CURR
CURR[10:8] This register reports 3 MSB bits of the magnitude of the average load current of the
selected Buck Converter. See LOAD_CURR register.
3 Reserved R/W 0
2:0 LOAD_CURRENT_ R/W 000 LOAD_CURRENT_SOURCE
SOURCE[2:0] These bits are used for choosing the Buck Converter whose load current will be
measured.
000 = Converter 0 load current will be measured.
001 = Converter 1 load current will be measured.
010 = Converter 2 load current will be measured.
011 = Converter 3 load current will be measured.
100 = Converter 4 load current will be measured.
101 = Converter 5 load current will be measured.
110 = Master total load current will be measured.
7.6.20 LOAD_CURR
Address: 0x22
D7 D6 D5 D4 D3 D2 D1 D0
BUCK_LOAD_CURR[7:0]
Bits Field Type Default Description
7:0 BUCK_LOAD_ R 0000 0000 BUCK_LOAD_CURR
CURR[7:0] This register reports 8 LSB bits of the magnitude of the average load current of the
selected Buck Converter. The value is reported with a resolution of 10 mA per LSB
and 20A max current. Three MSB bits are reported by
SEL_I_LOAD.BUCK_LOAD_CURR[10:8] bits, see SEL_I_LOAD.
The current reported is an average over the last 5 milliseconds. The host system has
read-only access to this register. This register is cleared to 0 on all resets.
000 0000 0000 Load current lower than 10 mA
000 0000 0001 10 mA Load current < 20 mA
...
111 1111 1110 20460 mA Load current < 20470 mA
111 1111 1111 Load current 20470 mA or higher.
Note: Not production tested. Typical values for reference only.
7.6.21 INT_MASK_2
Address: 0x2E
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D7 D6 D5 D4 D3 D2 D1 D0
Reserved MASK_ILOAD_ MASK_UVLO MASK_TWARN MASK_TEMP
READY ING
Bits Field Type Default Description
7:4 Reserved R/W 0000
3 MASK_ILOAD_ R/W 1 Interrupt mask for load current measurement flag
READY 1 = FLAGS_1.I_LOAD_READY does not set interrupt.
0 = FLAGS_1.I_LOAD_READY sets interrupt.
2 MASK_UVLO R/W 0 Interrupt mask for undervoltage lock-out flag
1 = FLAGS_1.UVLO does not set interrupt.
0 = FLAGS_1.UVLO sets interrupt, when triggered.
1 MASK_ R/W 1 Interrupt mask for thermal warning flag
TWARNING 1 = FLAGS_1.T_WARNING does not set interrupt.
0 = FLAGS_1.T_WARNING sets interrupt, when triggered.
0 MASK_TEMP R/W 1 Interrupt mask for die temperature flag bits
1 = FLAGS_0.TEMP[1:0] value change does not set interrupt.
0 = FLAGS_0.TEMP[1:0] value change sets interrupt.
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10 PF
10 PF
SYSTEM VOLTAGE
2.5..5.0V
100
nF
VINB0B1
VINB2
VINB5
VINB3B4
VDDA5V
VIOSYS
VIO1V8
SDASR
SCLSR
VLDO
1 PF
CLDO
CIN1
CIN2
CIN3
CIN4
CVDDA
0.47/1PH
SWB0
0.47/1PH
L1
L2
SWB1
CPU
LOAD
15A
MAX
OUTPUT
VOLTAGE
SWB3
LP8755: 6-PHASE
CONFIGURATION
RP3
RP4
VIO1V8
RP5
SDASYS
SCLSYS
INT
NSLP
GNDs
ADDR
NRST
APPLICATIONS
PROCESSOR
SWB2
0.47/1PH
0.47/1PH
0.47/1PH
0.47/1PH
SWB4
SWB5
L3
L4
L5
L6
COUT6PH
4 x 22 PF
FBB0+
FBB0-
FBB2
FBB3+
FBB3-
FBB5
CPU SENSE
10 PF
10 PF
CPU POWER REQUEST
LP8755
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8 Application and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
8.1 Application Information
The LP8755 is a multi-phase step-down converter with 6 switcher cores bundled together.
8.2 Typical Application
Figure 23. Six-Phase Configuration Scheme
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Typical Application (continued)
8.2.1 Design Requirements
Table 6 shows requirements for 6-phase configuration.
Table 6. Design Parameters
DESIGN PARAMETER EXAMPLE VALUE
Input voltage range 2.5 V to 5 V
Output voltage 1.1 V
Converter operation mode Forced PWM
Maximum load current 15 A
Inductor current limit 3 A
8.2.2 Detailed Design Procedure
The performance of the LP8755 device depends greatly on the care taken in designing the Printed Circuit Board
(PCB). The use of low inductance and low serial resistance ceramic capacitors is strongly recommended, while
proper grounding is crucial. Attention should be given to decoupling the power supplies. Decoupling capacitors
must be connected close to the IC and between the power and ground pins to support high peak currents being
drawn from System Power Rail during turn-on of the switching MOSFETs. Keep input and output traces as short
as possible, because trace inductance, resistance and capacitance can easily become the performance limiting
items. The separate power pins VINBXX are not connected together internally. The VINBXX power connections
shall be connected together outside the package using power plane construction.
8.2.2.1 Inductor Selection
The DC bias current characteristics of inductors must be considered. Different manufacturers follow different
saturation current rating specifications, so attention must be given to details. (Please request DC bias curves
from the manufacturer as part of the inductor selection process.) Minimum effective value of inductance to
ensure good performance is 0.25 µH at 3.2 A (Default ILIMITP typical) bias current over the inductor's operating
temperature range. The inductor’s DC resistance should be less than 0.05 for good efficiency at high-current
condition. The inductor AC loss (resistance) also affects conversion efficiency. Higher Q factor at switching
frequency usually gives better efficiency at light load to middle load. Table 7 lists suggested inductors and
suppliers. Shielded inductors radiate less noise and are preferable.
Table 7. Suggested Inductor Selection
ITEM MODEL VENDOR DIMENSIONS LXWXH D.C.R (m)
(mm) MAX
L1 to L6; Step-down XFL4015-471ME_(1) Coilcraft 4 .0 x 4.0 x 1.5 8.4
converter inductor 0.47 µH LQH32PNR47NN0(2) Murata 3.2 x 2.5 x 1.55 30 ± 20 %
DFE252012 R47(3) TOKO 2.5 x 2 x 1.2 39
DFE201612C R47N(4) TOKO 2.0 x 1.6 x 1.2 50
LQM2MPNR47MGH(4) Murata 2.0 x 1.6 x 1.0 46
L1 to L6; Step-down DFE322512 R68 TOKO 3.2 x 2.5 x 1.2 37
converter inductor 0.68 µH
L1 to L6; Step-down DFE322512 1R0 TOKO 3.2 x 2.5 x 1.2 45
converter inductor
1 µH
(1) Best efficiency.
(2) Good balance between size and efficiency.
(3) Satisfactory compromise between size and efficiency.
(4) Applications for which solution size is critical, efficiency compromised on very high loads.
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8.2.2.2 Input Capacitor Selection
A ceramic input capacitor of 10 µF, 10 V is sufficient for most applications. Place the input capacitor as close as
possible to the VINBXX pin and GND pin of the device. A larger value or higher voltage rating may be used to
improve input voltage filtering. Use X7R or X5R types, do not use Y5V. DC bias characteristics of ceramic
capacitors must be considered when selecting case sizes like 0402. Minimum effective input capacitance to
ensure good performance is 2.5 µF at maximum input voltage DC bias including tolerances and over ambient
temp range, assuming that there is at least 22 µF of additional capacitance common for all the power input pins
on the system power rail.
The input filter capacitor supplies current to the PFET (high-side) switch in the first half of each cycle and
reduces voltage ripple imposed on the input power source. A ceramic capacitor's low equivalent series resistance
(ESR) provides the best noise filtering of the input voltage spikes due to this rapidly changing current. Select an
input filter capacitor with sufficient ripple current rating.
For additional noise immunity, adding a high-frequency decoupling capacitor of 100 nF to 1 µF between VDDA5V
pin and GND is recommended.
Table 8. Suggested Input Capacitors (X5R Dielectric)
MANUFACTURER PART NUMBER VALUE CASE SIZE VOLTAGE RATING
Murata GRM188R60J106ME84 10 µF (20%) 0603 6.3 V
TDK C1608X5R1A106KT 10 µF (10%) 0603 10 V
Taiyo Yuden LMK107BJ106MALTD 10 µF (20%) 0603 10 V
Samsung CL10A226MP8NUNE 22 µF (20%) 0603 10 V
8.2.2.3 Output Capacitor Selection
Use ceramic capacitor, X7R or X5R types; do not use Y5V. DC bias voltage characteristics of ceramic capacitors
must be considered. DC bias characteristics vary from manufacturer to manufacturer, and DC bias curves should
be requested from them as part of the capacitor selection process. The output filter capacitor smooths out current
flow from the inductor to the load, helps maintain a steady output voltage during transient load changes and
reduces output voltage ripple. These capacitors must be selected with sufficient capacitance and sufficiently low
ESR to perform these functions. Minimum effective output capacitance to ensure good performance in 6-phase
configuration is 30 µF at the output voltage DC bias including tolerances and over ambient temp range.
The output voltage ripple is caused by the charging and discharging of the output capacitor and also due to its
RESR. The RESR is frequency dependent (as well as temperature dependent); make sure the value used for
selection process is at the switching frequency of the part.
A higher output capacitance improves the load step behavior and reduces the output voltage ripple as well as
decreasing the PFM switching frequency. For most 6-phase applications 4 x 22-µF 0603 capacitors for COUT is
suitable. Although the converter's loop compensation can be programmed to adapt to virtually several hundreds
of microfarads COUT, an effective COUT less than 120 µF is preferred -- there is not necessarily any benefit to
having a COUT higher than 120 µF. Note that the output capacitor may be the limiting factor in the output voltage
ramp, especially for very large (> 100 µF) output capacitors. For large output capacitors, the output voltage might
be slower than the programmed ramp rate at voltage transitions, because of the higher energy stored on the
output capacitance. Also at start-up, the time required to charge the output capacitor to target value might be
longer. At shutdown, if the output capacitor is discharged by the internal discharge resistor, more time is required
to settle VOUT down as a consequence of the increased time constant.
Table 9. Suggested Output Capacitor
MANUFACTURER PART NUMBER VALUE CASE SIZE VOLTAGE RATING
Samsung CL10A226MP8NUNE 22 µF (20%) 0603 10 V
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8.2.2.4 LDO Capacitor Selection
A ceramic low ESR 1-μF capacitor should be connected between the VLDO and GNDA pins.
Table 10. Suggested LDO Capacitor
MANUFACTURER PART NUMBER VALUE CASE SIZE VOLTAGE RATING
Samsung CL03A105MQ3CSNH 1 µF (20%) 0201 6.3 V
8.2.2.5 VIOSYS Capacitor Selection
Adding a ceramic low ESR 1-μF capacitor between the VIOSYS pin and GND is recommended. If VVIOSYS signal
is low noisy the capacitor is not required.
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70
75
80
85
90
95
100
2500 3000 3500 4000 4500 5000
EFFICIENCY (%)
INPUT VOLTAGE (mV)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C003
OUTPUT CURRENT = 6A
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
70
75
80
85
90
95
100
2500 3000 3500 4000 4500 5000
EFFICIENCY (%)
INPUT VOLTAGE (mV)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C003
OUTPUT CURRENT = 10A
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
70
75
80
85
90
95
100
2500 3000 3500 4000 4500 5000
EFFICIENCY (%)
INPUT VOLTAGE (mV)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C003
OUTPUT CURRENT = 3A
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
30
40
50
60
70
80
90
100
1 10 100 1000
EFFICIENCY (%)
OUTPUT CURRENT (mA)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
1650 mV Low Power
1400 mV Low Power
1150 mV Low Power
900 mV Low Power
650 mV Low Power
C006
V
IN
= 3.8V Inductor: TOKO
DFE252012C 470nH
PFM to PWM transition
50
60
70
80
90
100
0 2500 5000 7500 10000 12500 15000
EFFICIENCY (%)
OUTPUT CURRENT (mA)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C002
V
IN
= 2.8V
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
50
60
70
80
90
100
0 2500 5000 7500 10000 12500 15000
EFFICIENCY (%)
OUTPUT CURRENT (mA)
1650 mV
1400 mV
1150 mV
900 mV
650 mV
C001
V
IN
= 3.8V
fSW = 4.0MHz
Inductor: TOKO
DFE252012C 470nH
LP8755
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8.2.3 Application Curves
Unless otherwise specified: VVDDA5V = VVINBXX = 3.7 V, VOUT = 1.1 V, TA= 25°C
Figure 24. Efficiency vs Load Current in PWM Mode; VOUT Figure 25. Efficiency vs Load Current in PWM Mode; VOUT
Settings = 650 mV, 950 mV, 1150 mV, 1400 mV and 1650 Settings = 650 mV, 950 mV, 1150 mV, 1400 mV and 1650
mV mV
Figure 26. Light Load Efficiency, PFM and Low Power Figure 27. Efficiency vs Input Voltage in PWM Mode; VOUT
Mode Enabled; VOUT Settings = 650 mV, 950 mV, 1150 mV, Settings = 650 mV, 950 mV, 1150 mV, 1400 mV and 1650
1400 mV and 1650 mV. PFM_EXIT_B0[2:0] = 100b (225 mA) mV
Figure 28. Efficiency vs Input Voltage in PWM Mode; VOUT Figure 29. Efficiency vs Input Voltage in PWM Mode; VOUT
Settings = 650 mV, 950 mV, 1150 mV, 1400 mV and 1650 Settings = 650 mV, 950 mV, 1150 mV, 1400 mV and 1650
mV mV
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0.0
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
11.0
12.0
13.0
14.0
15.0
0
2000
4000
6000
8000
10000
12000
14000
16000
0 2000 4000 6000 8000 10000 12000 14000 16000
ACCURACY (%)
IOUT MEASURED BY LP8755 (mA)
REAL IOUT (mA)
IOUT
Accuracy
C009
0.0
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
0
500
1000
1500
2000
2500
0 2000 4000 6000 8000
ACCURACY (%)
PHASE CURRENT (mA)
TOTAL IOUT (mA)
Phase 0
Phase 1
Phase 2
Accuracy
C008
1148.0
1148.5
1149.0
1149.5
1150.0
2500 3000 3500 4000 4500 5000
OUTPUT VOLTAGE (mV)
INPUT VOLTAGE (mV)
0.0
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
0
500
1000
1500
2000
2500
0 5000 10000 15000
ACCURACY (%)
PHASE CURRENT (mA)
TOTAL IOUT (mA)
Phase 0
Phase 1
Phase 2
Phase 3
Phase 4
Phase 5
Accuracy
C008
1.090
1.092
1.094
1.096
1.098
1.100
1.102
1.104
1.106
1.108
1.110
±60 ±40 ±20 0 20 40 60 80 100 120 140
VOUT (V)
T (C)
PFM, Iload = 100mA
PWM, Iload = 3A
C028
VIN = 3.7V, VOUTSET = 1100mV
C004
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Figure 30. Output Voltage vs Load Current in Different Figure 31. Output Voltage vs Temperature
Modes
Figure 32. Line Regulation; ILOAD = 1 A; VOUTSET = 1150 mV Figure 33. Phase Currents and Current Balancing
Accuracy, 6 Phases Active (Currents measured by
LP8755)
Figure 34. Phase Currents and Current Balancing Figure 35. Load Current Measured by LP8755 vs Real Load
Accuracy, 3 Phases Active (Currents measured by Current, 6 Phases Active
LP8755)
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TIME 40 Ps/DIV
VOUT AC COUPLED
10 mV/DIV
VIN 500 mV/DIV
VOUT AC COUPLED
10 mV/DIV
TIME 200 ns/DIV
SW 1 V/DIV
TIME 10 Ps/DIV
lLOAD 400 mA/DIV
VOUT AC COUPLED
20 mV/DIV
TIME 10 Ps/DIV
lLOAD 200 mA/DIV
VOUT AC COUPLED
20 mV/DIV
VOUT AC COUPLED
20 mV/DIV
lLOAD 2 A/DIV
TIME 10 Ps/DIV
0.0
1.0
2.0
3.0
4.0
5.0
6.0
7.0
8.0
9.0
10.0
11.0
12.0
13.0
14.0
15.0
0
1000
2000
3000
4000
5000
6000
7000
8000
0 1000 2000 3000 4000 5000 6000 7000 8000
ACCURACY (%)
IOUT MEASURED BY LP8755 (mA)
REAL IOUT (mA)
IOUT
Accuracy
C010
LP8755
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Figure 36. Load Current Measured by LP8755 vs Real Load Figure 37. Transient Load Step Response; PWM mode,
Current, 3 Phases Active IOUT 1 A 8 A 1 A, tRISE = tFALL= 400 ns
Figure 38. Transient Load Step Response; PWM mode, Figure 39. Transient Load Step Response; AUTO mode,
IOUT 0.6 A 2 A 0.6 A, tRISE = tFALL= 400 ns IOUT 0.5 mA 500 mA 0.5 mA, tRISE = tFALL= 100 ns
Figure 40. Transient Line Response; IOUT = 2000 mA DC Figure 41. Output Voltage Ripple, PWM Mode. IOUT = 200
mA; One Phase Active
44 Submit Documentation Feedback Copyright © 2013–2015, Texas Instruments Incorporated
Product Folder Links: LP8755
TIME 400us/DIV
VOUT 200mV/DIV
TIME 100ms/DIV
lLOAD 1A/DIV
VOUT AC COUPLED 10mV/DIV
lL_B0 200mA/DIV
VIN 500mV/DIV
NRST 2 V/DIV
VOUT 200 mV/DIV
SW 5 V/DIV
TIME 20 Ps/DIV
LOAD 1 A/DIV
TIME 10ms/DIV
VOUT 500mV/DIV
IL 500mA/DIV
VNRST 2V/DIV
VOUT 200 mV/DIV
TIME 20 Ps/DIV
SW 5 V/DIV
NRST 2 V/DIV
TIME 400 Ps/DIV
VOUT AC COUPLED
10 mV/DIV
SW 1 V/DIV
LP8755
www.ti.com
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
Figure 42. Output Voltage Ripple, PFM Mode. IOUT = 100 µA Figure 43. Start-up with NRST, No Load
Figure 45. Shutdown with NRST, VIN = 3.7 V, VOUT = 1.1 V,
Figure 44. Start-up with NRST, 3-A Load No Load, Forced PWM
Figure 46. Load ramp 4.5 A 0 A 4.5 A Figure 47. VOUT Transition from 0.6 V to 1.4 V with
Different Ramp Settings, VIN = 3.7 V
Copyright © 2013–2015, Texas Instruments Incorporated Submit Documentation Feedback 45
Product Folder Links: LP8755
TIME 10 Ps/DIV
VOUT 200 mV/DIV
INT 500 mV/DIV
SW 2 V/DIV
TIME 400 Ps/DIV
VOUT 200 mV/DIV
INT 500 mV/DIV
LOAD 5 A/DIV
LP8755
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
www.ti.com
Figure 48. Interrupt Line Going Low with Not Power Good Figure 49. Metallic Short Applied at VOUT
Activation
46 Submit Documentation Feedback Copyright © 2013–2015, Texas Instruments Incorporated
Product Folder Links: LP8755
LP8755
www.ti.com
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
9 Power Supply Recommendations
The device is designed to operate from an input voltage supply range between 2.5 V and 5 V. This input supply
should be well regulated and able to withstand maximum input current and maintain stable voltage without
voltage drop even at load transition condition. The resistance of the input supply rail should be low enough that
the input current transient does not cause too high drop in the LP8755 supply voltage that can cause false UVLO
fault triggering. If the input supply is located more than a few inches from the LP8755 additional bulk capacitance
may be required in addition to the ceramic bypass capacitors.
10 Layout
10.1 Layout Guidelines
The high frequency and large switching currents of the LP8755 make the choice of layout important. Good power
supply results will only occur when care is given to proper design and layout. Bad layout will affect noise pickup
and generation and can cause a good design to perform with less-than-expected results. With a range of output
currents from milliamps to 10 A and over, good power-supply layout is more challenging than for most general
PCB design. The following steps should be used as a reference to ensure the device is stable and maintains
proper voltage and current regulation across its intended operating voltage and current range:
1. Place CIN as close as possible to the VINBXX pin and the GND pin. Route the VIN trace wide and thick to
avoid IR drops. The trace between the input capacitor's positive node and LP8755’s VINBXX pin(s) as well
as the trace between the input capacitor's negative node and power GND pin(s) must be kept as short as
possible. The input capacitance provides a low-impedance voltage source for the switching converter.
2. The output filter for each buck, consisting of COUT and L, converts the switching signal at SW to the noiseless
output voltage. For optimal EMI behavior, it should be placed as close as possible to the device, keeping the
switch node small. Route the traces between the LP8755's output capacitors and the load's input capacitors
direct and wide to avoid losses due to the IR drop.
3. Input for analog blocks (VDDA5V and GNDA) should be isolated from noisy signals. Connect VDDA5V
directly to a quiet system voltage node and GNDA to a quiet ground point where no IR drop occurs. For
additional noise immunity, adding a high-frequency decoupling capacitor of 100 nF to 1 µF is recommended.
Place the decoupling capacitor as close to the VDDA5V pin as possible. VDDA5V trace is low current, so the
trace width does not need to be optimized.
4. If the processor load supports voltage remote sensing, connect the LP8755 feedback pins FBBXX to the
respective sense pins on the processor. The sense lines are susceptible to noise. They must be kept away
from noisy signals such as GNDBXX, VIN, and SW, as well as high bandwidth signals such as the I2C. Avoid
both capacitive as well as inductive coupling by keeping the sense lines short, direct, and close to each
other. Run the lines in a quiet layer. Isolate them from noisy signals by a voltage or ground plane if possible.
Running the signal as a differential pair is recommended.
5. GNDBXX, VIN, and SW should be routed on thick layers. They must not surround inner signal layers which
are not able to withstand interference from noisy GNDBXX, VIN, and SW. This can create noise coupling to
inner signal layers.
Due to the small package of this converter and the overall small solution size, the thermal performance of the
PCB layout is important. Many system-dependent issues such as thermal coupling, airflow, added heat sinks and
convection surfaces, and the presence of other heat-generating components affect the power dissipation limits of
a given component. Proper PCB layout, focusing on thermal performance, results in lower die temperatures.
Wide power traces come with the ability to sink dissipated heat. This can be improved further on multi-layer PCB
designs with vias to different planes. This results in reduced junction-to-ambient (RθJA) and junction-to-board
(RθJB) thermal resistances, thereby reducing the device junction temperature, TJ. It's strongly recommended to
perform a careful system-level 2D or full 3D dynamic thermal analysis at the beginning of the product design
process, using a thermal modeling analysis software.
Copyright © 2013–2015, Texas Instruments Incorporated Submit Documentation Feedback 47
Product Folder Links: LP8755
CIN6
Via to GND plane
Via to VIN plane
SW
B3
INT
FB
B0+/
B0
NSLP
SW
B0
SW
B0
GND
B1/
B2
GND
B1/
B2
SW
B2
SW
B2
VIN
B2
SDA
SYS
VDD
A5V
SCL
SYS
FB
B3+/
B3
SW
B4
VIN
B0/
B1
VIN
B2
ADD
R
GND
B4/
B5
FB
B3-/
B4
SCL
SR
FB
B5
VIN
B0/
B1
SW
B1
VIN
B0/
B1
SW
B1
FB
B0-/
B1
FB
B2
NRS
T
SW
B5
GND
B4/
B5
VIN
B3/
B4
GND
B1/
B2
SDA
SR
VIN
B3/
B4
GND
B3
VIO
SYS
GND
A
VLD
O
GND
B0
GND
B0
SW
B3
VIN
B5 SW
B4
SW
B5
GND
B4/
B5
VIN
B3/
B4
GND
B3
CVDDA
CLDO
CVIOSYS
CIN0
CIN1
CIN2
CIN3
COUT1
L2
L3
L1
L4
L0
L5
VOUT
GND
VIN
VIN
VIN GND
GND VIN
VIN
GND
GND
CIN5
Pin A1
CIN7
CIN4
COUT3
GND
COUT2
COUT0
LP8755
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
www.ti.com
10.2 Layout Example
Figure 50. LP8755 Board Layout
48 Submit Documentation Feedback Copyright © 2013–2015, Texas Instruments Incorporated
Product Folder Links: LP8755
LP8755
www.ti.com
SNVSA20A NOVEMBER 2013REVISED FEBRUARY 2015
11 Device and Documentation Support
11.1 Device Support
11.1.1 Third-Party Products Disclaimer
TI'S PUBLICATION OF INFORMATION REGARDING THIRD-PARTY PRODUCTS OR SERVICES DOES NOT
CONSTITUTE AN ENDORSEMENT REGARDING THE SUITABILITY OF SUCH PRODUCTS OR SERVICES
OR A WARRANTY, REPRESENTATION OR ENDORSEMENT OF SUCH PRODUCTS OR SERVICES, EITHER
ALONE OR IN COMBINATION WITH ANY TI PRODUCT OR SERVICE.
11.2 Documentation Support
11.2.1 Related Documentation
For related documentation, see the following:
Texas Instruments Application Note DSBGA Wafer-Level Chip-Scale Package (SNVA009).
11.3 Trademarks
SmartReflex is a trademark of Texas Instruments Incorporated.
All other trademarks are the property of their respective owners.
11.4 Electrostatic Discharge Caution
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage.
ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more
susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.
11.5 Glossary
SLYZ022 TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
12 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
Copyright © 2013–2015, Texas Instruments Incorporated Submit Documentation Feedback 49
Product Folder Links: LP8755
PACKAGE OPTION ADDENDUM
www.ti.com 4-Sep-2015
Addendum-Page 1
PACKAGING INFORMATION
Orderable Device Status
(1)
Package Type Package
Drawing Pins Package
Qty Eco Plan
(2)
Lead/Ball Finish
(6)
MSL Peak Temp
(3)
Op Temp (°C) Device Marking
(4/5)
Samples
LP8755KME/NOPB NRND DSBGA YFQ 49 250 Green (RoHS
& no Sb/Br) SNAGCU Level-1-260C-UNLIM -40 to 85 8755
LP8755KMX/NOPB NRND DSBGA YFQ 49 1000 Green (RoHS
& no Sb/Br) SNAGCU Level-1-260C-UNLIM -40 to 85 8755
(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.
(4) There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5) Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6) Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
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.
PACKAGE OPTION ADDENDUM
www.ti.com 4-Sep-2015
Addendum-Page 2
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.
MECHANICAL DATA
YFQ0049xxx
www.ti.com
TMD49XXX (Rev A)
A
. All linear dimensions are in millimeters. Dimensioning and tolerancing per ASME Y14.5M-1994.
B. This drawing is subject to change without notice.
NOTES:
4215087/A 12/12
0.600±0.075
D
E
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