TI TPS65800RTQ

TPS65800
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
SINGLE-CELL Li-ION BATTERY- AND POWER-MANAGEMENT IC
FEATURES
L2
SM2
AGND1
VIN_SM1
L1
PGND1
SM1
GPIO1
49 48
47
46 45
44
43
PGND2
50
GPIO2
52 51
RED
56
VIN_SM2
PDAs
Smart Phones
MP3s
Internet Appliances
Handheld Devices
GPIO3
55
54
53
BLUE
1
42
SM3
SCLK
2
41
FB3
SDA T
3
40
SM3SW
R TC_OUT
4
39
L3
5
38
PGND3
6
37
LDO1
7
36
LED_PWM
SIM
USB
AC
GROUND PAD
OUT
8
35
VIN_LDO02
OUT
32
LDO0
TS
12
TMR
13
DPPM
14
21 22
23
24
ANLG1
20
25 26
AGND2
LDO5
18 19
ADC_REF
16 17
INT
15
27
28
LDO3
11
LDO4
LDO2
ISET1
ANLG2
PWM
33
RESPWRON
34
10
TRSTPWON
9
LDO_PM
BA T
•
•
•
•
•
BA T
•
APPLICATIONS
GREEN
•
•
– 8-channel integrated A/D samples system
parameters with single conversion, peak
detection, or averaging operating modes
HOST INTERFACE
– Host can set system parameters and
access system status using I2C interface
– Interrupt function with programmable
masking signals system status modifiction
to host
– 3 GPIO ports, programmable as drivers,
integrated A/D trigger or buck converters
standby mode control
AGND0
•
BATTERY CHARGER
– Complete charge management solution for
single Li-Ion/Li-Pol cell with thermal
foldback, dynamic power management,
and pack temperature sensing, supporting
up to 1.5-A maximum charge current
– Programmable charge parameters for AC
adapter and USB port operation
INTEGRATED POWER SUPPLIES
– A total of 9 LDOs are integrated:
– Six adjustable output LDOs (1.25-V to
3.3-V)
– Two fixed-voltage LDOs (3.3-V)
– One RTC backup supply with low
leakage (3.1-V)
– Two 600-mA, programmable dc/dc buck
converters (0.6-V to 3.4-V) with enable,
standby-mode operation, and automatic
low-power mode setting
DISPLAY FUNCTIONS
– Two open-drain PWM outputs with
programmable frequency and duty cycle.
Can be used to control keyboard backlight,
vibrator, or other external peripheral
functions
– RGB LED driver with programmable
flashing period and individual R/G/B
brightness control
– Constant-current white LED driver, with
programmable current level, brightness
control, and overvoltage protection can
drive up to 6 LEDs in series configuration
SYSTEM MANAGEMENT
– Dual input power path function with input
current limiting and OV protection
– POR function with programmable masking
monitors all integrated supplies outputs
– Software and hardware reset functions
HOT_RST
•
31
SYS_IN
30
LDO35_REF
29
VIN_LDO35
QFN 56-Pin, 8 x 8 mm Package
(Top View - Not To Scale)
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2005–2007, Texas Instruments Incorporated
TPS65800
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
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.
DESCRIPTION
The TPS65800 provides an easy to use, fully integrated solution for handheld devices, integrating charge
management, multiple regulated power supplies, system management and display functions, in a small
thermally-enhanced 8x8-mm package. The high level of integration enables typical board area space savings of
70% when compared to equivalent discrete solutions, while implementing a high-performance and flexible
solution, portable across multiple platforms. If required, an external host may control the TPS65800 via I2C
interface, with access to all integrated systems. The I2C enables setting output voltages, current thresholds, and
operation modes. Internal registers have a complete set of status information, enabling easy diagnostics, and
host-controlled handling of fault conditions. The TPS65800 can operate in stand-alone mode, with no external
host control, if the internal power-up defaults are compatible with the system requirements
AVAILABLE OPTIONS (1)
(1)
(2)
(3)
(4)
2
TJ
DEVICES (2) (3) (4)
MARKING
–40°C to 125°C
TPS65800RTQ
TPS65800
For the most current package and ordering information, see the Package Option Addendum at the end
of this document, or see the TI Web site at www.ti.com.
The RTQ package is available in tape and reel. Add R suffix (TPS65800RTQR) to order quantities of
2000 parts per reel. Add T suffix (TPS65800RTQT) to order quantities of 250 parts per reel.
This product is RoHS compatible, including a lead concentration that does not exceed 0.1% of total
product weight, and is suitable for use in specified lead-free soldering processes. In addition, this
product uses package materials that do not contain halogens, including bromine (Br) or antimony (Sb)
above 0.1% of total product weight.
Other power-up sequences and default power-up states for the supplies can be implemented upon
request. Consult factory for available options.
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
FUNCTIONAL BLOCK DIAGRAM
TPS65800
AC
OUT
OUT
USB
LDO_PM
LDO_PM
3.3V
10 mA
SIM,RTC LDOS
SIM
1.8V/3.3V
8 mA
BAT
BAT
BAT
ON/OFF
AGND1
OUT
OUT
RTC_OUT
OUT
POWER PATH
CONTROL
LINEAR
CHARGER
SYSTEM
POWER
CHARGE
MANAGEMENT
AGND1
TS
DPPM
TMR
ISET1
OUT
AGND1
3.1V
8 mA
AGND1
VIN_LDO12
LDO0
LDO0,1,2
3.3V
150 mA
AGND1
LDO1
LDO2
1.25V-3.3V
150 mA
LDO3
LDO4
PWM
DRIVER
PWM
RGB
DRIVER
RED
GREEN
BLUE
GPIO’S
GPIO1
GPIO2
GPIO3
LED_PWM
DISPLAY AND I /O
OUT
1.25V-3.3V
150 mA
L3
SM3
SM3_SW
WHITE LED
DRIVER
AGND1
VIN_LDO35
FB3
PGND3
CONTROL
LOGIC
LDO3,4,5
1.224V-4.4V
100 mA
VIN_SM1
DC/DC
0.6-1.8V
600 mA
1.224V-4.4V
100 mA
L1
SM1
PGND1
VIN_SM2
LDO35_REF
LDO5
1.224V-4.4V
100 mA
L2
1.0V-3.4V
600 mA
AGND2
SM2
PGND2
OUT
6 INTERNAL
CHANNELS
HOST INTERFACE AND
SEQUENCING
SCLK
SDAT
INT
SYS_IN
HOT_RST
RESPWRON
TRSTPWON
I2C INTERFACE
AND INTERRUPT
CONTROLLER
AGND 1
AGND1
OUT
ADC
INTERNAL BIAS
RESET
CONTROLLER
AGND0
DISPLAY AND I /O
OUT
REFERENCE
SYSTEM
AGND1
8 CHANNEL
MUX
ANLG1
A/D
CONVERTER
ADC_REF
ANLG2
AGND2
AGND 0, AGND1, AND AGND2 PINS SHORTED TO EACH OTHER INSIDE TPS 65800
. ALL AGND PINS ARE INTERNALLY CONNECTED TO
THE TPS 65800 THERMAL PAD AND SUBSTRATE.
PGND 1, PGND2, AND PGND3 PINS ARE NOT CONNECTED TO EACH OTHER OR TO THE TPS65800 SUBSTRATE / POWER PAD
Figure 1. TPS65800 simplified block diagram
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ABSOLUTE MAXIMUM RATINGS
over operating free-air temperature range (unless otherwise noted) (1)
VALUE
AC and USB with respect to AGND1
ANLG1, ANLG2 with respect to AGND2
–0.3 to V(OUT)
V(OUT) with respect to AGND1
5
VIN_LDO12, VIN_LDO35, LDO3, LDO4, LDO5 with respect to AGND2
–0.3 to V(OUT)
LDO35_REF, ADC_REF with respect to AGND2
–0.3 to smaller of: 3.6 or V(OUT)
SIM, RTC_OUT with respect to AGND1
–0.3 to smaller of: 3.6 or V(OUT)
SM1, L1, VIN_SM1 with respect to PGND1
–0.3 to V(OUT)
SM2, L2, VIN_SM2 with respect to PGND2
–0.3 to V(OUT)
SM3, L3 with respect to PGND3
–0.3 to 29
SM3SW with respect to PGND3
–0.3 to V(OUT)
FB3 with respect to PGND3
–0.3 to V(OUT)
AGND2, AGND0, PGND1, PGND2, PGND3 with respect to AGND1
2750
Input Current, USB pin
600
Output continuous current, OUT pin
3000
Output conitnuous current, BAT pin
–3000
Continuous Current at L1, PGND1, L2, PGND2
1800
Operating free-air temperature
Maximum junction temperature
TSTG
Storage temperature
(1)
–0.3 to +0.3
Input Current, AC pin
TJ
mA
–40 to 85
125
–65 to 150
Lead temperature 1,6 mm (1/16-inch) from case for 10 seconds
260
ESD rating, all pins
1.5
°C
kV
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only and functional operation of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
DISSIPATION RATINGS
PACKAGE
RTQ
(1)
(2)
4
V
–0.3 to 0.5
All other pins (except AGND and PGND), with respect to AGND1
TA
UNIT
–0.3 to 18
(1) (2)
θJA
TA≤ 55°C
POWER RATING
DERATING FACTOR
ABOVE TA = 55°C
21.7°C/W
3.22 W
0.046 W/°C
This data is based on using the JEDEC High-K board and the exposed die pad is connected to a Cu
pad on the board. This is connected to the ground plane by a via matrix.
The RTQ package MSL level: HIR3 at 260°C
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
RECOMMENDED OPERATING CONDITIONS
MIN
MAX
4.35
16.5 (1)
V
0
2.6
V
Greater of: 3.6 V OR minimum input
voltage required for LDO/converter
operation outside dropout region
4.7
AC and USB with respect to AGND1
ANLG1, ANLG2 with respect to AGND2
VIN_LDO35 with respect to AGND2
VIN_LDO12 with respect to AGND1
4.7
VIN_SM2 with respect to PGND2
4.7
SM3 with respect to PGND3
TA
4.7
VIN_SM1 with respect to PGND1
Operating free-air temperature
TJ(o Junction temperature, functional operation assured
UNIT
V
28
V
–40
85
°C
–40
125
°C
0
125
°C
p)
TJ
(1)
Junction temperature, electrical characteristics assured
Thermal operating restrictions are reduced or avoided if input voltage does not exceed 5 V.
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – I2C INTERFACE
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in figure (unless otherwise noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
I2C TIMING CHARACTERISTICS
tr
SCLK/SDATA rise time
300
tf
SCLK/SDATA fall time
tw(H)
SCLK pulse duration, high
600
tw(L)
SCLK pulse duration, low
1.3
tSU(STA)
Setup time for START condition
600
tH(STA)
START condition hold time after which first clock pulse is generated
600
tSU(DAT)
Data setup time
100
tH(DAT)
Data hold time
tSU(STOP)
Setup time for STOP condition
600
t(BUF)
Bus free time between START and STOP condition
1.3
FSCL
Clock frequency
300
ns
µs
ns
0
µs
400
kHz
I2C INTERFACE LOGIC LEVELS
VIH
High level input voltage
1.3
6
VIL
Low level input voltage
0
0.4
IH
Input bias current
µA
0.01
tsu(STA)
tw(L)
tw(H)
tf
tr
SCL
tr
tf
SDA START
th(STA)
SCL
th(DAT)
th(DAT)
tsu(DAT)
1
2
3
STOP
7
8
9
ACK
SDA
START
tsu(STOP)
SCL
1
2
3
7
8
9
ACK
SDA
t(BUF)
STOP
Figure 2. I2C Timing
6
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – SYSTEM SEQUENCING AND OPERATING MODES
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
QUIESCENT CURRENT
IBAT(SLEEP)
BAT pin current, sleep
mode set
Input power not detected, V(BAT) = 4.2 V, Sleep mode set
IBAT(DONE)
BAT pin current, charge
terminated
Charger function enabled by I2C, termination detected, input
power detected and selected
3
IBAT(CHGOFF)
BAT pin current, charge
function OFF
Charger function disabled by I2C, termination not detected,
input power detected and selected
3
IINP(CHGOFF)
AC or USB pin current,
charge function OFF
Charger function disabled by I2C, termination not detected,
input power detected and selected. All integrated supplies
and drivers OFF, no load at OUT pin.
370
µA
200
UNDERVOLTAGE LOCKOUT
VUVLO
Internal UVLO detection
threshold
NO POWER mode set at V(OUT) < VUVLO,
V(OUT) decreasing
VUVLO_HYS
UVLO detection
hysteresis
V(OUT) increasing
tDGL(UVLO)
UVLO detection deglitch
time
Falling voltage only
–3%
2.5
3%
V
120
mV
5
ms
SYSTEM LOW VOLTAGE THRESHOLD
VLOW_SYS
Minimum system voltage System voltage V(SYS_IN) decreasing, SLEEP mode set if
detection threshold
V(SYS_IN) < VLOW_SYS
VHYS(LOWSYS)
Minimum system voltage
V(SYS_IN) increasing
detection hysteresis
50
mV
tDGL(LOWSYS)
Minimum system voltage
V(SYS_IN) decreasing
detection deglitch time
5
ms
0.97
1
1.03
V
THERMAL FAULT
TSHUT
Thermal shutdown
Increasing junction temperature
165
THYS(SHUT)
Thermal shudown
hysteresis
Decreasing junction temperature
30
°C
INTEGRATED SUPPLY POWER FAULT DETECTION
VPGOOD
Power-good fault
detection threshold
Falling output voltage, applies to all integrated supply
outputs. Referenced to the programmed output voltage value
85%
90%
93%
VHYS(PGOOD)
Power-good fault
detection hysteresis
Rising output voltage, applies to all integrated supply outputs.
Referenced to VPGOOD threshold
3%
5%
7%
HOT RESET FUNCTION
VHRSTON
Low-level input voltage
RESET mode set at V(HOT_RESET) < VHRSTON
VHRSTOFF
High level input voltage
HOT reset not active at V(HOT_RESET) > VHRSTOFF
tDGL(HOTRST)
Hot reset input deglitch
0.4
1.3
5
V
ms
SYSTEM RESET – OPEN DRAIN OUTPUT RESPWRON
VRSTLO
Low level output voltage
IIL = 10 mA, V(RESPWRON ) < VRSTLO
ITRSTPWON
Pullup current source
Internally connected to TRSTPWRON pin
KRESET
Reset timer constant
TRESET = KRESET× CTRSTPWON
0
0.9
1.0
1
0.3
V
1.12
µA
ms/nF
SEQUENCING DELAYS
tDLY(D1)
Sequencing delay
See sequencing timing diagram
0.24
tDLY(D1)
Sequencing delay
See sequencing timing diagram
12
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ELECTRICAL CHARACTERISTICS – POWER PATH AND CHARGE MANAGEMENT
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
VOLTAGE DETECTION THRESHOLDS
VIN(DT)
Input Voltage detection
threshold
AC detected at V(AC)– V(BAT) > VIN(DT);
USB detected at V(USB)– V(BAT) > VIN(DT)
VIN(NDT)
Input Voltage removal
threshold
AC not detected at V(AC)– V(BAT) < VIN(NDT);
USB not detected at V(USB)– V(BAT) < VIN(NDT)
tDGL(NDT)
Power not detected deglitch
VSUP(DT)
Supplement detection
threshold
Battery switch ON at V(BAT) – V(OUT) > VSUP(DT)
60
VSUP(NDT)
Supplement not detected
threshold
Battery switch OFF at V(BAT)– V(OUT) < VSUP(NDT)
20
190
mV
125
22.5
ms
mV
POWER PATH INTEGRATED MOSFETs CHARACTERISTICS
VACDO
AC switch dropout voltage
VACDO = V(AC)– V(OUT); V(AC) = 4.75 V AC input current limit set to 2.75 A
(typ), IO(OUT) = 1.0 A
VUSBDO
USB switch dropout voltage
VUSBDO = V(USB)– V(OUT); V(USB) = 4.6 V
USB input current limit set to 2.75 A (typ)
VBATDODCH
Battery switch dropout
voltage, discharge
VBATDOCH
Battery switch dropout
voltage, charge
350
375
I(OUT) + I(BAT)= 0.5 A
175
190
I(OUT) + I(BAT)= 0.1 A
35
45
V(BAT): 3 V → VCH(REG), I(BAT) = –1 A
60
100
Charger on, V(BAT): 3 V → 4.2 V, I(BAT) = 1 A
60
100
mV
POWER PATH INPUT CURRENT LIMIT
IINP(LIM1)
Selected Input current limit,
applies to USB input only
Selected input switch not in dropout, I2C settings: ISET2 = LO,
PSEL = LO
IINP(LIM2)
Selected Input current limit,
applies to USB input only
Selected input switch not in dropout, I2C settings: ISET2 = HI, PSEL = LO
IINP(LIM3)
Selected Input current limit,
applies to either AC or USB
input
Selected input switch not in dropout, I2C settings: ISET2 = HI OR LO,
PSEL = HI
80
100
400
500
mA
2.75
A
4.7
V
SYSTEM REGULATION VOLTAGE
VSYS(REG)
Output regulation voltage
VSYS(REG) = V(OUT), DPPM loop not active, selected input current limit not
reached. Selected input voltage (AC or USB) > 5.1 V
4.6
POWER PATH PROTECTION AND RECOVERY FUNCTIONS
VINOUTSH
Input-to-output short-circuit
detection threshold
AC and USB switches set to OFF if V(OUT) < VINOUTSH
0.6
RSH(USBSH)
OUT short circuit recovery
pullup resistor
V(OUT) < 1 V, internal resistor connected from USB to OUT
500
RSH(ACSH)
OUT short circuit recovery
pullup resistor
V(OUT) < 1 V, internal resistor connected from AC to OUT
500
Overvoltage detection
threshold
Rising voltage, overvoltage detected when V(AC) > VOVP or
V(USB) > VOVP
Overvoltage detection
hysteresis
Falling voltage, relative to detection threshold
0.1
VBATOUTSH
Battery to Output short
circuit detection threshold
BAT switch set to OFF if V(BAT)-V(OUT)> VBATOUTSH
200
KBLK(SHBAT)
Battery-to-ouput short-circuit
blanking time constant
V(DPPM) < 1v, tBLK(SHBAT) = KBLK(SHBAT)× CDPPM, CDPPM capacitor is
connected from DPPM pin to AGND1
ISH(BAT)
OUT short circuit recovery
pullup current source
V(BAT) – V(OUT) > VBATOUTSH,
internal current source connected between OUT and BAT
RSH(BAT)
BAT short circuit recovery
resistor
V(BAT)< 1 V,
Internal resistor connected from OUT to BAT
RDCH(BAT)
BAT pulldown resistor
Internal resistor connected from BAT to AGND1 when battery is not detected
by ANLG1
VOVP
8
V
Ω
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6
6.5
6.8
V
mV
1
ms/nF
10
mA
1
kΩ
500
Ω
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – POWER PATH AND CHARGE MANAGEMENT (Continued)
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
120
200
300
ms
POWER PATH TIMING CHARACTERISTICS, DPPM AND THERMAL LOOPS NOT ACTIVE, RTMR = 50 kΩ
tBOOT
Boot-up time
Measured from input power detection
tSW(ACBAT)
Switching from AC to BAT
No USB: measured from V(AC)– V(BAT) < VIN(NDT), USB
detected:CE=LO (after CE hold-off time)
50
tSW(USBBAT)
Switching from USB to BAT
No AC: measured from V(USB)– V(BAT) < VIN(NDT),USB
detected:CE=LO (after CE hold-off time)
50
tSW(PSEL)
Switching from USB to AC
Toggling
tSW(ACUSB)
Switching from AC to USB or USB to
AC
AC power removed or USB power removed
I2C
µs
50
PSEL bit
100
BATTERY REMOVAL DETECTION
VNOBATID
Battery ID resistor detection
tDGL(NOBAT)
Deglitch time for battery removal
detection
ID resistor not detected at V(OUT)– V(ANLG1) < VNOBATID
0.6
00, V(OUT): 2.5 V to 4.4 V
IO(ANLG1)
ANLG1 pullup current
0.5
Set via I2C bits
(BATID1,BATID2)
ADC_WAIT register
1.2
ms
V(OUT) * 1.2
500 kW
01
10
10
50
11
60
Total accuracy
V
µA
25%
25%
100
1500
FAST CHARGE CURRENT, V(OUT) > V(BAT) + 0.1 V, V(BAT) > VLOWV
IO(BAT)
VSET
KSET
Charge current range
Battery charge current set voltage
Battery charge current set factor
K(SET)
IO(BAT) +
V(SET)
RSET
VSET = V(ISET1),
(ISET1_1, ISET1_0) =
11, 100% scaling
2.475
2.500
2.525
10, 75% scaling
1.875
1.900
1.925
01, 50% scaling
1.225
1.250
1.275
00, 25% scaling
0.625
0.575
0.600
100 mA < IO(BAT)≤ 1 A
350
400
450
1 mA < IO(BAT)≤ 100 mA
100
400
1000
mA
V
PRECHARGE CURRENT, V(OUT) > V(BAT) + 0.1 V, VBATSH < V(BAT) < VLOWV, t < t(PRECHG)
V(PRECHG)
K(SET)
IO(PRECHG)
Precharge current range
IO(PRECHG) +
VPRECHG
Precharge set voltage
VPRECHG = V(ISET1)
220
VLOWV
Precharge to fast-charge transition
Fast charge at V(BAT) > VLOWV
2.8
tDGL(PRE)
Deglitch time for fast charge to
precharge transition
Decreasing battery voltage, RTMR = 50 kΩ
RSET
10
150
mA
250
270
mV
3
3.2
V
22.5
ms
CHARGE REGULATION VOLTAGE, V(OUT) > VO(BATREG) + 0.1V
4.2
Voltage options, selection via I2C
VO(BATREG)
Battery charge voltage
V
4.356
Accuracy, TA = 25°C
Total accuracy
–0.5%
0.5%
–1%
1%
10
150
CHARGE TERMINATION, V(BAT) > VRCH, VOLTAGE REGULATION MODE SET
V(TERM)
K(SET)
ITERM
Charge termination current range
I(TERM) +
VTERM
Battery termination detection set
voltage
VTERM = V(ISET1),
(ISET1_1, SET1_0) =
tDGL(TERM)
Deglitch time for termination detection
V(ISET1) < VTERM, RTMR = 50 kΩ
RSET
11, 100% scaling
240
260
280
10, 75% scaling
145
160
175
01, 50% scaling
90
110
130
00, 25% scaling
40
60
75
Submit Documentation Feedback
22.5
mA
mV
ms
9
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – POWER PATH AND CHARGE MANAGEMENT (Continued)
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
80
100
130
mV
BATTERY RECHARGE DETECTION
VRCH
Recharge threshold voltage
New charge cycle starts if V(BAT) < VO(BATREG)– VRCH, after
termination was detected
tDGL(RCH)
Deglitch time for recharge detection
RTMR = 50 kΩ
22.5
ms
DPPM FUNCTION
VDPPM
DPPM regulation point range
V(DPPM) = RDPPM× KDPPMM× IO(DPPM)
2.6
4.4
V
IO(DPPM)
DPPM pin current source
AC or USB Present
95
100
105
µA
KDPPM
DPPM scaling factor
1.139
1.15
1.162
tDGL(DPPM)
DPPM de-glitch time
Status bit set indicating DPPM loop active after deglitch time,
RTMR = 50 kΩ
µs
500
PACK TEMPERATURE SENSING
VLTF
Low-temperture threshold
Pack low temperature fault at V(TS) > VLTF
2.465
2.5
2.535
VHTF
High-temperture threshold
Pack low temperature fault at V(TS) < VHTF
0.485
0.5
0.515
IO(TS)
Temperature-sense current source
Thermistor bias current
18.8
20
21.2
tDLG(TFAULT
Deglitch time for temperature fault
detection
R(TMR) = 50 kΩ,
V(TS) > VLTF OR V(TS) < VHTF
)
22.5
V
µA
ms
CHARGE AND PRECHARGE SAFETY TIMER
tCHG
Charge safety timer programmed
value
KTMR
Charge timer set factor
tCHGADD
Total elapsed time when DPPM or
thermal loop are active
Fast charge on, tCHGADD is the maximum add-on time added to
tCHG
tPRECHG
Precharge safety timer programmed
value
Precharge safety timer range, thermal/DPPM loop not active,
tPRECHG = KPRE× RTMR× KTMR
KPRE
Precharge timer set factor
tPCHGADD
Total elapsed time when DPPM or
thermal loop are active
RTMR
External timer resistor limits
RTMR(FLT)
Timer fault recovery pullup resistor
Safety timer range, thermal/DPPM loop not active,
tCHG = RTMR× KTMR
3
5
10
0.313
0.360
0.414
2 × tCHG
30
60
0.09
0.1
0.11
2 × tPRECHG
30
Internal resistor connected from OUT to BAT after safety timer
timeout
s/Ω
h
18
Precharge on, tPCHGADD is the maximum add-on time added to
tPRECHG
h
min
h
100
1
kΩ
kΩ
CHARGER THERMAL SHUTDOWN
TTHCHG
Charger thermal shutdown
TTHCHGHYS
Charger thermal shutdown hystersis
Charger turned off when TJ> TTHCHG
150
°C
30
THERMAL REGULATION LOOP
TTHREG
10
Temperature regulation limit
Charge current decreasesd and timer extended when TJ >
TTHREG
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115
135
°C
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – LINEAR REGULATORS
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SELECTABLE OUTPUT VOLTAGE LDOS: LDO1, LDO2
IQ(LDO12)
Quiescent current, either LDO1
I
= I(VIN_LDO02)
or LDO2 enabled, LDO0 disabled Q(LDO12)
IO(LDO1,2)
Output current range
I(LDO1,2) = –1 mA
15
I(LDO1,2) = –150 mA
150
Output voltage, selectable via I2C.
Available output voltages:
VO(LDO1,2)TYP = 1.25, 1.5, 1.8,
2.5, 2.85, 3, 3.2, 3.3
Dropout voltage, 150 mA load
VO(LDO1,2)
LDO1, LDO2 output voltage
µA
160
300
Total accuracy, V(VIN_LDO02) = 3.65 V
–3%
3%
Line regulation, 100-mA load,
V(VIN_LDO02): V(LDO1,2)TYP + 0.5 V → 4.7 V
–1%
1%
–1.5%
1.5%
Load regulation, load: 10 mA → 150 mA
V(VIN_LDO02) > VO(LDO1,2) TYP + 0.5 V
PSR(LDO12)
PSRR at 20 kHz
ISC(LDO1,2)
LDO1&2 short-circuit current limit Output grounded
150-mA load at output, V(VIN_LDO02) – VO(LDO1,2) = 1 V
RDCH(LDO1,2)
Discharge resistor
LDO disabled by I2C command
ILKG(LDO1,2)
Leakage current
LDO off
tSSLDO1,2
Soft start ramp time
tSS_DELAYLDO1,2
Startup delay
mA
V
mV
40
dB
300
mA
300
Ω
2
µA
500
µs
Measured from the time when the enable bit is set
20
µs
Internally connected to OUT pin
20
SIM LINEAR REGULATOR
IQ(SIM)
Quiescent current
IO(SIM)
Output current range
Output voltage, selectable via I2C.
Available output voltages:
VO(SIM)TYP = 1.8 or 3
Dropout voltage, 8-mA load
VO(SIM)
SIM LDO output voltage
µA
8
–5%
5%
Load regulation, load: 1 mA → 8 mA,
V(OUT) > VO(SIM) TYP + 0.5 V
–3%
3%
Line regulation, 5 mA load, V(OUT):
VO(SIM) TYP + 0.5 V → 4.7 V
–2%
2%
Short Circuit current limit
Output grounded
ILKG(SIM)
Leakage current
LDO off
V
0.2
Total accuracy, V(OUT): 3.2 V to 4.7 V, 8 mA
ISC(SIM)
mA
20
mA
1
µA
70
µA
PROGRAMMABLE OUTPUT VOLTAGE LDO’S: LDO3, LDO4, LDO5
IQ(LDO35)
Quiescent current, only one of
LDO3, LDO4, LDO5 is enabled
IO(LDO35)
Output current range
IQ(LDO35) = I(VIN_LDO35)
100
Output voltage, selectable via I2C
Available output voltages:
VO(LDO35)TYP = 1.224 V to
4.46 V, 25 mV steps
Dropout voltage, 100-mA load
VO(LDO35)
LDO3, LDO4, LDO5 output
voltage
240
Total accuracy, 100-mA load V(VIN_LDO35) = 5 V
–3%
3%
Load regulation,
V(VIN_LDO35) > VO(LDO35)TYP + Load: 1 mA → 50 mA
0.5 V
–1%
1%
Line regulation, 10 mA load,
V(VIN_LDO35): VO(LDO35)TYP + 0.5 V → 4.7 V
–1%
1%
ISC(LDO35)
Short-circuit current limit
Output grounded
PSR(LDO35)
PSRR at 10 kHz
V(VIN_LDO35) > VO(LDO3,5) +1 V, 50-mA load at output
RDCH(LDO35)
Discharge resistor
LDO is disabled by
ILKG(LDO35)
Leakage current
LDO off
tSSLDO3,5
Soft-start ramp time
tSS_DELAYLDO3,5
Startup delay
I2C
command
Measured from the time when the enable bit is set
Submit Documentation Feedback
mA
V
mV
250
mA
40
dB
400
Ω
1
µA
120
µs
70
µs
11
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – LINEAR REGULATORS (continued)
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
RTC_OUT LINEAR REGULATOR
IQ(RTC_OUT)
Quiescent current for RTC LDO
IO(RTC_OUT)
Output current range
Internally connected to OUT pin
Fixed output voltage value
ISH(RTC_OUT)
ILKG(RTC_OUT)
RTC_OUT output voltage
8
mA
200
mV
3.1
Dropout voltage, I(RTC_OUT) = –8 mA
VO(RTC_OUT)
µA
20
V
Total accuracy, V(OUT): 2 V to 4.7 V, 8-mA load,
sleep mode not set
–5%
5%
Load regulation, load: 1 mA → 8 mA, 2 V < V(OUT) < 4.7 V
–3%
3%
Line regulation, 5-mA load,
V(OUT): 2 V → 4.7 V
–2%
2%
Short circuit current limit
V(RTC_OUT) = 0 V
Leakage current
V(RTC_OUT) = 1.5 V,
V(OUT) = 0 V
TJ = 85°C
880
20
TJ = 25°C
250
Internally connected to VIN_LDO12
pin
I(LDO0) = –1 mA
mA
nA
LDO0 LINEAR REGULATOR
IQ(LDO0)
Quiescent current
IO(LDO0)
Output current range
15
I(LDO0) = –150 mA
Fixed output voltage value
Output voltage
150
mA
300
mV
3.3
Dropout voltage, I(LDO0) = –150 mA
VO(LDO0)
µA
160
V
Total accuracy
–3%
3%
Line regulation, V(OUT): VO(LDO0)+ 0.5 → 4.7 V,
I(LDO0) =– 100 mA
–1%
1%
Load regulation, I(LDO0) = –10 mA →– 150 mA
–1.5%
PSR(LDO0)
PSRR at 20 kHz
150 mA load at output, V(VIN_LDO12) – VO(LDO1,2) = 1 V
ISC(LDO0)
Short-circuit current limit
V(LDO0) = 0 V
ILKG(LDO0)
Leakage current
LDO off
TSSLDO0
Soft start ramp time
TSS_DELAYLDO0
Startup delay
1.5%
40
dB
300
mA
1
µA
500
µs
Measured from the time when the enable bit is set
20
µs
Fixed output voltage value, V(OUT) > 4 V
3.3
Dropout voltage, I(LDOPM) = –12 mA
0.5
LDO_PM LINEAR REGULATOR
IQ(LD0_PM)
Output current range
VO(LDO_PM)
Output voltage
ILKG(LDOPM)
Leakage current
20
Total accuracy
12
LDO off
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–5%
0.7
mA
V
5%
1
µA
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – SWITCHED MODE SM1 STEP DOWN CONVERTER
Over recommended operating conditions (typical values at TJ = 25°C), VO(SM1) = 1.24 V, application circuit as in Figure 3
(unless otherwise noted).
PARAMETER
IQ(SM1)
Quiescent current for SM1
IO(SM1)
Output current range
VO(SM1)
Output voltage, PWM mode
TEST CONDITIONS
MIN
TYP MAX
IQ(SM1) = I(VIN_ SM1), no output load, not switching
10
SM1 OFF, set via I2C
0.1
20
600
Output voltage, selectable via I2C, standby OFF
Available output
voltages: VO(SM1)TYP =
0.6 V to 1.8 V,
adjustable in 40-mV
steps
VO(SM1) = VSBY(SM1), output voltage range, standby ON
Available output
voltages: VSBY(SM1) =
0.6 V to 1.8 V,
adjustable in 40-mV
steps
Total accuracy, VO(SM1)TYP = VSBY(SM1) = 1.24 V,
V(VIN_SM1) = 3 V to 4.7 V; 0 mA ≤ IO(SM1)≤ 600 mA
–3%
0.027
Load regulation, V(VIN_SM1) = 4.7 V,
IO(SM1): 60 mA → 540 mA
0.139
RDSON(PSM1)
P-channel MOSFET
on-resistance
ILKG(PSM1)
P-channel leakage current
RDSON(NSM1)
N-channel MOSFET
on-resistance
ILKG(PSM1)
N-channel leakage current
ILIM(SM1)
P- and N-channel current limit
3 V < V(VIN_SM1) < 4.7 V
900
fS(SM1)
Oscillator frequency
PWM mode set
1.3
EFF(SM1)
Efficiency
V(VIN_SM1) = 4.2 V, PWM mode, IO(SM1) = 300 mA,
VO(SM1) = 3 V
tSS(SM1)
Soft start ramp time
Converter OFF→ON, VO(SM1): 5% → 95% of target
value
750
tDLY(SM1)
Converter turn-on delay
GPIO1 pin programmed as SM1 converter enable
control. Measured from V(GPIO1): LO → HI
170
310
V
%/A
500
220
330
mΩ
µA
1050 1200
1.5
mΩ
µA
5
Submit Documentation Feedback
mA
%/V
0.1
V(VIN_SM1) = 3.6 V, 0% duty cycle set
µA
3%
Line regulation, V(VIN_SM1): 3 → 4.7 V,
IO(SM1) = 10 mA
V(VIN_SM1) = 3.6 V, 100% duty cycle set
UNIT
1.7
mA
MHz
90%
µs
13
TPS65800
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – SWITCHED MODE SM2 STEP DOWN CONVERTER
Over recommended operating conditions (typical values at TJ = 25°C), VO(SM1) = 1.24 V, application circuit as in Figure 3
(unless otherwise noted).
PARAMETER
IQ(SM2)
Quiescent current for SM2
IO(SM2)
Output current range
VO(SM2)
Output voltage
TEST CONDITIONS
MIN
TYP MAX
IQ(SM2) = I(VIN_ SM2), no output load, not switching
10
SM2 OFF, set via I2C
0.1
20
600
Output voltage, selectable via I2C, standby OFF
Available output
voltages: VO(SM2)TYP = 1
V to 3.4 V, adjustable in
80 mV steps
VO(SM2) = VSBY(SM2), output voltage range, standby
ON
Available output
voltages: VSBY(SM2) = 1
V to 3.4 V, adjustable in
80-mV steps
Total accuracy, VO(SM2)TYP = VSM2(SBY) = 1.8 V,
V(VIN_SM2) = greater of [3 V or (VO(SM2) + 0.3 V)]
to 4.7 V; 0 mA ≤ IO(SM2)≤ 600 mA
–3%
UNIT
µA
mA
V
3%
Line regulation, V(VIN_SM2) = greater of
[3 V or (VO(SM2) + 0.3 V)]
to 4.7 V; 0 mA ≤ IO(SM2)≤ 600 mA
0.027
%/V
Load regulation, V(VIN_SM2) = 4.7 V,
IO(SM2): 60 mA → 540 mA
0.139
RDSON(PSM2)
P-channel MOSFET
on-resistance
ILKG(PSM2)
P-channel leakage current
RDSON(NSM2)
N-channel MOSFET
on-resistance
ILKG(PSM2)
N-channel leakage current
ILIM(SM2)
P- and N- channel current limit
3 V < V(VIN_SM2) < 4.7 V
900
fS(SM2)
Oscillator frequency
PWM mode set
1.3
EFF(SM2)
Efficiency
V(VIN_SM2) = 4.2 V, IO(SM2) = 300 mA,
VO(SM2) = 3 V
tSS(SM2)
Soft start ramp time
Converter OFF→ON, VO(SM2) : 5% → 95% of target
value
750
tDLY(SM2)
Converter turn-on delay
GPIO2 pin programmed as SM2 converter enable
control. Measured from V(GPIO2): LO → HI
170
V(VIN_SM2) = 3.6 V, 100% duty cycle set
310
%/A
500
µA
0.1
V(VIN_SM2) = 3.6 V, 0% duty cycle set
220
330
mΩ
µA
5
1050 1200
1.5
mΩ
1.7
mA
MHz
92%
µs
ELECTRICAL CHARACTERISTICS – GPIOs
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
GPIO1–3
VOL
Low level output voltage GPIO0
IOL = 20 mA
IOGPIO
Low level sink current into GPIO1, 2, 3
V(GPIOn) = V(OUT)
VIL
Low level input voltage
ILKG(GPIO)
Input leakage current
14
0.5
20
0.4
V(GPIOn) = V(OUT)
Submit Documentation Feedback
V
mA
1
V
µA
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – ADC
Over recommended operating conditions (typical values at TJ = 25°C), V(ADC_REF) =2.535v if external reference voltage is
used,application circuit as in Figure 3 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
ANALOG INPUTS
VRNG(CH1_5)
Full-scale input range, Ch1 to
Ch5
Positive inputs (active clamp), full scale ~ 2.535 V
0
V(ADC_
REF)
VRNG(CH6_8)
Full-scale input range, Ch6 to
Ch8
Positive inputs (active clamp), full scale ~4.7 V
0
VINTREF
× 1.854
CIN(ADC)
Input capacitance (all channels)
RINADC(CH1_5)
15
Input resistance
(Ch1 to Ch5)
ILKGADC(CH1_5) Leakage current
(Ch1 to Ch5)
RINADC(CH6_8)
Input resistance
(Ch6 to Ch8)
ILKGADC(CH6_8) Leakage current
(Ch6 to Ch8)
VCH5(ADC)
Internal voltage proportional to
junction temperature
pF
1
MΩ
100
430
540
Temperature coefficient
nA
kΩ
10
TJ = 25°C, ADC channel 5 input voltage
V
µA
1.89
5
V
6.5
mV/
°C
10
Bits
DC ACCURACY
RES(ADC)
Resolution
MCD(ADC)
No missing codes
INL(ADC)
Integral linearity error
±3
LSB
DNL(ADC)
Differential non-linearity error
±1
LSB
OFFZERO(ADC) Offset error
SAR ADC
SPECIFIED
Difference between the first code transition (00...00
to 00...001) and the ideal AGND + 1 LSB
OFFCH(ADC)
Offset error match between
channels
GAINADC
Gain error
Deviation in code from the ideal full scale code
(11…111) for the full scale voltage
GAINCH(ADC)
Gain error match
Any two channels
5
LSB
5
LSB
±8
LSB
2
LSB
THROUGHPUT SPEED
ADCCLK
ADCTCONV
Sampling clock
Conversion time
650
750
850
kHz
Sampling, convertion and setting Rs ≤ 200 K for
Ch1, Ch2, Ch3; Rs ≤ 500 Ω for Ch6, Ch7, Ch8
44
59
68
µs
2.53
2.53
5
2.54
REFERENCE VOLTAGES
VINTREF
Internal ADC reference voltage
TA = 25°C, V(ADC_REF)=VINTREF when internal
ADC reference is selected
ISHRT(INTREF)
Internal reference short circuit
limit
V(ADC_REF)= AGND1, internal reference enabled
via I2C
VREF(DRIFT)
ADC internal reference
temperature drift
IQ(ADC)
ADC Internal reference
quiescent current
Measured at OUT pin (internal reference) or
ADC_REF pin (external reference)
ANLG2 pin internal pullup
current source
ADC channel 2 bias current, set via
I2C register ADC_WAIT bits
(ADC_CH2I_D1_1, ADC_CH2I _D2)
I(ANLG2)
6
50
0
01
10
10
50
11
Total accuracy, relative to selected value
Submit Documentation Feedback
mA
100
ppm/°
C
µA
40
00
V
µA
60
–25%
25%
15
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – ADC (continued)
Over recommended operating conditions (typical values at TJ = 25°C), V(ADC_REF) =2.535v if external reference voltage is
used,application circuit as in Figure 3 (unless otherwise noted).
PARAMETER
TEST CONDITIONS
MIN
00
I(ANLG1)
ANLG1 pin internal pullup
current source
ADC channel 1 bias current, set via
I2C register ADC_WAIT bits
(BATIDI_D1, BATIDI _D2)
TYP
01
10
10
50
11
Total accuracy
MAX
V(OUT) * 1.2
500 kW
UNIT
µA
60
10%
10%
INTERNAL REFERENCE POWER CONSUMPTION
PDACTIVE
Power dissipation
Conversion active
PDARMED
Power dissipation
Not converting
2.3
mW
0.43
mW
TRIGGER TIMING CHARACTERISTICS
tDELAY(TRG)
Trigger delay time accuracy
Time range, set via I2C register ADC_DELAY
Relative to typical value set via I2C
tWAIT(TRG)
Trigger wait time accuracy
Time range, set via I2C register ADC_WAIT
Relative to typical value set via I2C
0
750
–20%
20%
0
20.48
–20%
20%
µS
mS
ELECTRICAL CHARACTERISTICS – LED AND PWM DRIVERS
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SM3 BOOST CONVERTER, WHITE LED CONSTANT-CURRENT DRIVER
VVIN(SM3)
Input Voltage range
V(OUT) = 3.3 V
VOVP3
Output overvoltage trip
OVP detected at V(SM3) > VOVP3
3
VHYS(OVP3)
Output overvoltage hysteresis
OVP not detected at V(SM3) < VOVP3 – VHYS(OVP3)
VSM3REF
LED current sense threshold
LED current below regulation point at
V(FB3) < VSM3REF
IO(SM3)
LED current
Current range, Vin = 3.3 V,
IO(SM3) +
26.5
Total accuracy, IO(SM3) = 10mA
4.7
V
30
V
1.8
244
V(SM3REF)
RFB3
29
252
V
260
mV
0.5
25
mA
–10%
10%
DSM3SW = 0% to 99.6%, set
via I2C, 256 steps 0.4%
minimum step
DSM3SW
LED switch duty cycle
Duty cycle range
fREP_SM3
LED switch duty cycle pattern
repetition rate
256 pulses within repetition
rate time
RDSON(SM3SW)
LED switch MOSFET
on-resistance
V(OUT) = 3.6 V; I(SM3SW) = 20 mA
ILKG(SM3SW)
LED switch MOSFET leakage
RDSON(L3)
Power stage MOSFET
on-resistance
ILKG(L3)
Power stage MOSFET leakage
IMAX(L3)
Power stage MOSFET current
limit
SM3_LF_OSC = 0
122
SM3_LF_OSC = 1
183
Hz
1
2
300
600
400
500
mΩ
µA
1
3 V < V(OUT) < 4.7 V
Ω
µA
1
V(OUT) = 3.6 V; I(L3) = 200 mA
--
600
mA
0.5
V
PWM DRIVER, PWM OPEN DRAIN OUTPUT
VOL(PWM)
fPWM
Low level output voltage
PWM driver frequency
I(PWM) = 150 mA
Frequency range
Total accuracy, relative to selected value
tRISE_PWM
16
Rise time PWM voltage
IOL_PWM = 150 mA
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Set via I2C, fPWM =
0.5/1/1.5/2/3/4.5/7.8/15.6
– 20%
0.2
Hz
20%
1
2.8
µs
TPS65800
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
ELECTRICAL CHARACTERISTICS – LED AND PWM DRIVERS (continued)
Over recommended operating conditions (typical values at TJ = 25°C), application circuit as in Figure 3 (unless otherwise
noted)
PARAMETER
TEST CONDITIONS
tFALL_PWM
Fall time PWM voltage
IOL_PWM = 150 mA
DPWM
PWM driver duty cycle
Duty cycle range
MIN
TYP
MAX
0.2
1
2.8
UNIT
µs
DPWM = 6.25% to 100%,
set via I2C,
6.25% minimum step
--
LED_PWM DRIVER, LED_PWM OPEN DRAIN OUTPUT
DLEDPWM = 0% to 99.6%,
set via I2C, 256 steps
0.4% minimum step
DLEDPWM
LED_PWM driver duty cycle
Duty cycle range
fREP(LEDPWM)
LED_PWM driver duty cycle
pattern repetition rate
256 pulses within repetition
rate time
VOL(LEDPWM)
Low level output voltage
I(LED_PWM) = 150 mA
VOH(LEDPWM)
High level output voltage
tRISE_LEDPWM
Rise time PWM voltage
IOL_LEDPWM = 150 mA
0.2
tFALL_LEDPWM
Fall time PWM voltage
IOL_LEDPWM = 150 mA
0.2
SM3_LF_OSC = 0
122
SM3_LF_OSC = 1
180
Hz
0.5
V
6
V
1
2.8
µs
1
2.8
µs
RGB DRIVER, RED/GREEN/BLUE OPEN DRAIN OUTPUTS
tFLASH(RGB)
Flashing period
tFLASH(RGB) = 1 to 8 s, set
via I2C, 0.5 s minimum
step, 8 steps
Flashing period range
Total accuracy
–20%
s
20%
I2C,
tFLASH(ON)
Flash on time
Flash on time range, value selectable by I2C
Total accuracy, relative to selected value
DRGB
ISINK(RGB)
Duty cycle
Duty cycle range, value selectable via I2C
RGB output sink current
V(RED) = V(GREEN) =
V(BLUE) = 2 V, set via I2C
RGB_ISET1,0
Set via
tFLASH(ON) =
0.1/0.15/0.2/0.25/0.3/0.4/
0.5/0.6 s
– 20%
s
20%
DRGB = 0% to 99.98%, set
via I2C, 3.23% minimum
step
00 = (Driver set to
OFF)
01
2.4
4
5.6
10
4.8
8
11.2
11
7
12
16.6
mA
VOL(RGB)
Low level output voltage
Output low voltage, 8 mA load, RED/GREEN/BLUE
PINS
ILKG(RGB)
Output off leakage current
V(RED)=V(GREEN)=V(BLUE) = 4.7 V, all drivers
disabled
tRISE_RGB
Voltage rise time
8-mA load
2
5
8
µs
tFALL_RGB
Voltage fall time
8-mA load
2.4
5
8
µs
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0.3
V
µA
1
17
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
L2
VIN_SM2
SM2
AGND1
VIN_SM1
L1
PGND1
SM1
GPIO1
49 48
47
46 45
44
43
PGND2
50
GPIO2
52 51
RED
56
GPIO3
GREEN
PIN ASSIGNMENT
55
54
53
BLUE
1
42
SM3
SCLK
2
41
FB3
SDA T
3
40
SM3SW
R TC_OUT
4
39
L3
5
38
PGND3
6
37
LDO1
36
LED_PWM
SIM
USB
AC
7
GROUND PAD
VIN_LDO02
OUT
9
34
PWM
LDO_PM
10
33
LDO2
ISET1
11
32
LDO0
TS
12
TMR
13
DPPM
14
27
31
SYS_IN
30
LDO35_REF
29
VIN_LDO35
28
LDO3
25 26
LDO4
24
ANLG1
23
AGND2
LDO5
21 22
RESPWRON
20
INT
TRSTPWON
18 19
BA T
BA T
16 17
AGND0
HOT_RST
15
ANLG2
35
ADC_REF
OUT
8
PIN DESCRIPTION, REQUIRED EXTERNAL COMPONENTS
NAME
PIN
I/O
DESCRIPTION
AC
7
I
Adapter charge input voltage, connect to
AC_DC adapter positive output terminal
(dc voltage)
1-µF (minimum) capacitor to AGND1 pin to minimize
overvoltage transients during AC power hot-plug events.
ADC_REF
22
I/O
ADC internal reference filter or ADC
external reference input
4.7-µF (minimum) to 10-µF (maximum) capacitor connected to
AGND2 pin
AGND0
16
–
Analog ground connection
Connect to analog ground plane
AGND1
48
–
Analog ground pin
Connect to analog ground plane
AGND2
25
–
Analog ground pin
Connect to analog ground plane
ANLG1
24
I
Analog input to ADC, programmable
current source output
Can be used to monitor additional system or pack parameters
ANLG2
23
I
Analog input to ADC, programmable
current source output
Can be used to monitor additional system or pack parameters
BAT
17,
18
I/O
Battery power
Connect to battery positive terminal. Connect 10-µF capacitor
(minimum) from BAT pin to AGND1 pin.
BLUE
1
O
Programmable blue driver, open-drain
output, current sink output when active.
Connect to BLUE input of RGB LED
DPPM
14
I
Dynamic power path management
set-point
External resistor from DPPM pin to AGND1 pin sets the DPPM
regulation threshold. 1-nF (minimum) capacitor to from DPPM
to AGND1 sets BAT to OUT short-circuit blanking delay when
battery is hot-plugged into system.
FB3
41
I/O
White LED duty cycle switch output, LED
current setting
External resistor from FB3 pin to PGND3 pin sets LED peak
current. Connect 100-pF (minimum) filter capacitor to PGND3
pin.
GPIO1
43
I/O
General purpose programmable I/O
Example: External Interrupt request to host (INT:HI→LO)
GPIO2
53
I/O
General purpose programmable I/O
I/O Example: Set SM1 and SM2 converters in standby mode
GPIO3
54
I/O
General purpose programmable I/O
Example: ADC conversion start trigger
GREEN
56
O
Programmable LED driver, open drain
output, current sink output when active.
Connect to GREEN input of RGB LED
18
EXTERNAL REQUIRED COMPONENTS
(SEE APPLICATION DIAGRAM)
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
PIN ASSIGNMENT (continued)
NAME
PIN
I/O
DESCRIPTION
EXTERNAL REQUIRED COMPONENTS
(SEE APPLICATION DIAGRAM)
HOT_RST
15
I/O
Hardware reset input, reset generated
when connected to ground
Connect to an external push-button switch
INT
19
O
Interruption pin, open-drain output
Connect 100-kΩ external pullup resistor between INT and OUT
INT pin is LO when interrupt is requested by TPS65800.
ISET1
11
I
Current set point when charging in auto
External resistor from ISET1 pin to AGND1 pin sets charge
mode with AC selected. Precharge and
current value
charge termination set point for all charge
modes
L1
46
O
SM1 synchronous buck converter power
stage output
3.3-µH inductor to SM1 pin
L2
51
O
SM2 synchronous buck converter power
stage output
3.3-µH inductor to SM2 pin
L3
39
O
Drain of the integrated boost power stage 4.7-µH inductor to OUT pin, external Schottky diode to SM3
switch
pin
LDO0
32
O
LDO0 output, fixed voltage
1-µF (minimum) capacitor to AGND1
LDO1
37
O
LDO1 output
1-µF (minimum) capacitor to AGND1
LDO2
33
O
LDO2 output
1-µF (minimum) capacitor to AGND1
LDO3
28
O
LDO3 output
2.2-µF (minimum) capacitor to AGND2
LDO4
27
O
LDO4 output
2.2-µF (minimum) capacitor to AGND2
LDO35_REF
30
I
Linear regulators LDO3–5 reference filter
100-nF capacitor to AGND2
LDO5
26
O
LDO5 output
2.2-µF (minimum) capacitor to AGND2
LDO_PM
10
O
General-purpose LDO output
1-µF (minimum) capacitor to AGND1 pin
LED_PWM
36
O
PWM driver output, open-drain
Can be used to drive a keyboard backlight LED
OUT
8, 9
O
Power path output. Connect to system
main power rail (system power bus)
10-µF capacitor to AGND1 pin
PGND1
45
–
SM1 synchronous buck converter power
ground
Connect to power ground plane
PGND2
52
–
SM1 synchronous buck converter power
ground
Connect to power ground plane
PGND3
38
–
White LED driver power ground input.
Connect to a power ground plane
PWM
34
O
PWM driver output, open-drain
Can be used to drive a vibrator or other external functions
RED
55
O
Programmable LED driver, open drain
output, current sink output when active.
Connect to RED input of RGB LED
RESPWRON
21
O
System reset, open-drain output
100-kΩ external pullup resistor to OUT. RESPWRON pin is LO
when TPS65800 is resetting the system.
RTC_OUT
4
O
Low-leakage LDO output. Can be
connected to a super-capacitor or
secondary cell, if used as a RTC backup
output.
1-µF (minimum) capacitor to AGND1 pin or supercapacitor
SCLK
2
I
I2C interface clock line
2-kΩ pullup resistor to OUT pin
SDAT
3
I/O
I2C interface data line
2-kΩ pullup resistor to OUT pin
SIM
5
O
General-purpose LDO output
1-µF (minimum) capacitor to AGND1 pin
SM1
44
I
SM1 synchronous buck converter output
voltage sense
LC filter: 10-µF capacitor to PGND1 pin
SM2
49
I
SM2 synchronous buck converter output
voltage sense
LC filter: 10-µF capacitor to PGND2 pin
SM3
42
I
White LED driver output overvoltage
detection
Connect 1-µF capacitor to PGND3 pin. Connect SM3 pin to
the positive side of white LED ladder.
SM3SW
40
I
Integrated white LED duty cycle switch
input
Connect to negative side of external LED ladder
SYS_IN
31
I
System power bus low-voltage detection
External resistive divider sets minimum system operational
voltage. TPS65800 enters sleep mode when voltage below
minimum system voltage threshold is detected. 1 nF filter
capacitor to AGND1 recommended.
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
PIN ASSIGNMENT (continued)
NAME
PIN
I/O
TMR
13
I
Charge safety timer program input
External resistor from TMR pin to AGND1 pin sets the charge
safety timer time-out value.
TRSTPWON
20
I
System reset pulse duration setting
100-nF (minimum) capacitor to AGND1. External capacitor
from TRSTPWON pin to AGND1 pin sets RESPWRON pulse
duration
TS
12
I/O
Temperature sense input, current source
output
Connect to battery pack thermistor to sense battery pack
temperature
USB
6
I
USB charge input voltage, connect to
USB port positive power output
1-µF (minimum) capacitor to AGND1 pin, to minimize
overvoltage transients during USB power hot-plug events.
VIN_LDO35
29
–
Input to LDOs 3 to 5
1-µF (minimum) decoupling capacitor to AGND2
VIN_LDO02
35
–
Positive supply input for LDO0, LDO1,
LDO2
1-µF (minimum) decoupling capacitor to AGND1
VIN_SM1
47
–
SM1 synchronous buck converter positive 10-µF capacitor to PGND1 pin
supply input
VIN_SM2
50
–
SM2 synchronous buck converter positive 10-µF capacitor to PGND2 pin
supply input
Exposed
thermal pad
57
–
There is an internal electrical connection between the exposed thermal pad and AGNDn pins of the IC.
The exposed thermal pad must be connected to the same potential as the AGND1 pin on the printed
circuit board. Do not use the thermal pad as the primary ground input for the IC. AGNDn pins must be
connected to a clean ground plane at all times.
20
DESCRIPTION
EXTERNAL REQUIRED COMPONENTS
(SEE APPLICATION DIAGRAM)
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
APPLICATION DIAGRAM
+
VSIM
VRTC_OUT
VL DO_PM
VLDO0
VLDO1
VLDO2
AC_DC
ADAPTER
OUTPUT
-
GND
USB
POWER
+
C1 10uF
-
7 AC
C2 10uF
GND
C4
C5
VOUT
VOUT
6 USB
C3 2.2uF
Supercap
TPS65800
5 SIM
ISET1 11
4 RTC_OUT
1uF
BAT 17
A1
C6
C7
1uF
1uF
C8
4.7uF
C9
4.7uF
VOUT
DPPM 14
33 LDO2
C11
1uF
C12
0.1uF
C13
2.2uF
C14
2.2uF
C15
2.2uF
VLDO 3
V LDO5
A2
R1
VOUT
A1
C17
210K
R6
100K
R5
100K
4.7uF
C22
10uF
C21
10uF
LSM2
VSM2
3.3uH
C19
10uF
P2
LSM3
4.7uH
VOUT
D1
C28
1 uF
P3
SM3 42
2 SCLK
WHITE LEDS
3 SDAT
FB3 41
19 INT
PGND3 38
21 RESPWRON
C18
100 pF
RFB3
24 ANLG1
C27
100pF
10
P3
PWM 34
LED_PWM 36
23 ANLG2
EXTERNAL
PERIPHERALS
RED 55
43 GPIO1
VOUT
GREEN 56
BLUE 1
53 GPIO2
54 GPIO3
GND
VOUT
L3 39
22 ADC_REF
A2
VOUT
VSM1
3.3uH
PGND2 52
31 SYS_IN
R4
A1
LSM1
SM3SW 40
20 TRSTPWON
2K
Battery
P1
15 HOT_RST
R3
37.4K
VIN_SM2 50
L2 51
SM2 49
26 LDO5
25 AGND2
2K
49.9K
SM1 44
PGND1 45
28 LDO3
27 LDO4
R2
RTMR
C23 47nF
30 LDO35_REF
100K
C16 1nF
C25
10uF
RDPPM
VIN_SM1 47
L1 46
29 VIN_LDO35
CTRSTPWON 0.1uF
1K
C24
0.22uF
TS 12
TMR 13
32 LDO0
37 LDO1
48 AGND1
VLDO4
SYSTEM
POWER
BUS
RSET
BAT 18
35 VIN_LDO02
10 LDO_PM
C10 4.7uF
C26 22uF
OUT 8
OUT 9
PWRGND
57
AGND0 16
RGB LED
A0
A1
NOTES:
RESET
ADC
EXTERNAL
ANALOG
INPUTS
I2C
CONFIGURABLE
GPIO’S
1) RESISTOR VALUES IN OHMS
2) THE FOLLOWING PARAMETERS ARE PROGRAMMED :
ALARM
EXTERNAL HOST
DATA
CLOCK
- RTMR =49. 9K: 6 HOUR CHARGE SAFETY TIMER ,
30 MIN PRE -CHARGE SAFETY TIMER
- RSET =1K: 1A CHARGE CURRENT (NO SCALING, INPUT LIMIT=2.5A),
100mA TERMINATION AND PRE -CHARGE CURRENTS
- R FB3=10 OHMS: 25mA WHITE LED CURRENT
- C TRSTPWON =100nF : 100mSEC RESET PULSE WIDTH
- R DPPM =37.4K: V (DPPM ) =4.3V
3) THE CAPACITOR VALUES SHOWN IN THE APPLICATION DIAGRAM
MAY BE LARGER THAN THE MINIMUM REQUIRED VALUES INDICATED
IN THE PIN DESCRIPITON TABLE
4) THE VALUES SHOWN IN THE APPLICATION DIAGRAM MATCH THE
COMPONENT VALUES USED IN THE HPA 129 EVM, SEE DESIGN NOTES
SECTION FOR COMPONENT SELECTION DETAILS
GND A1 A2 A3 P1 P2 P3
Figure 3. TPS65800 Application Diagram, Recommended External Components
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
TYPICAL CHARACTERISTICS – POWER PATH MANAGEMENT
Measured with application circuit shown in Figure 3, unless otherwise noted
SWITCHING FROM AC TO BATTERY
ON AC REMOVAL
SWITCHING FROM USB TO BATTERY
ON AC REMOVAL
USB = 5 V,
BAT = 3.3 V
AC = 5 V,
BAT = 3.3 V
IBAT
IBAT
VAC
VUSB
VOUT
VBAT
VOUT
Figure 4.
22
VBAT
Figure 5.
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
TYPICAL CHARACTERISTICS – LINEAR REGULATORS 0, 1, 2
Measured with application circuit shown in Figure 3, unless otherwise noted
LOAD REGULATION
vs
JUNCTION TEMPERATURE
LINE REGULATION
vs
JUNCTION TEMPERATURE
0.25
-0.500
VIN_LDO02 = 3.65 V,
Load = 10 mA to 150 mA,
CO(LDO02) = 1 mF
0.2
-0.600
Line Regulation - %
Load Regulation - %
-0.550
-0.650
-0.700
0.15
0.1
-0.750
VIN_LDO02 = 3.8 V to 4.7 V,
Load = 10 mA,
CO(LDO02) = 1 mF
0.05
-0.800
-0.850
0
0
20
40
60
80
100
120
0
140
20
40
60
80
100
120
140
120
140
TJ - Junction Temperature - °C
TJ - Junction Temperature - °C
Figure 6.
Figure 7.
OUTPUT VOLTAGE
vs
JUNCTION TEMPERATURE
DROPOUT VOLTAGE
vs
JUNCTION TEMPERATURE
140
3.5
LDO 0
VIN_LDO 02 = 3.3 V,
Load = 150 mA, CO(LDO02) = 1 mF
130
Dropout Voltage - mV
VO - Output Voltage - V
3
2.5
VIN_LDO 02 = 3.65 V, Load = 10 mA,
VO(LDO 0) = 3.3 V, VO(LDO 1,2) = 1.225 V
2
120
110
100
90
LDO 1
LDO 2
1.5
80
1
70
0
20
40
60
80
100
120
140
0
20
40
60
80
100
TJ - Junction Temperature - °C
TJ - Junction Temperature - °C
Figure 8.
Figure 9.
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
TYPICAL CHARACTERISTICS – LINEAR REGULATORS 3, 4, 5
Measured with application circuit shown in Figure 3, unless otherwise noted
LOAD REGULATION
vs
JUNCTION TEMPERATURE
LINE REGULATION
vs
JUNCTION TEMPERATURE
-0.010
-0.5
VIN_LDO 35 = 3 V,
Load = 10 mA to 150 mA,
CO(LDO 35) = 1 mF
-0.55
-0.012
Line Regulation - %
Load Regulation - %
-0.6
VIN_LDO 35 = 3.3 V to 4.7 V,
Load = 100 mA,
CO(LDO 35) = 1 mF
-0.011
-0.65
-0.70
-0.75
-0.80
-0.013
-0.014
-0.015
-0.85
-0.016
-0.90
-0.017
-0.95
-1
-0.018
0
20
40
60
80
100
TJ - Junction Temperature - °C
120
140
0
40
60
80
100
TJ - Junction Temperature - °C
Figure 10.
Figure 11.
OUTPUT VOLTAGE
vs
JUNCTION TEMPERATURE
DROPOUT VOLTAGE
vs
JUNCTION TEMPERATURE
1.2325
120
140
140
VIN_LDO35 = 4.7 V,
Load = 10 mA,
VO (LDO35) = 1.228 V,
1.232
130
CO(LDO35) = 1 mF
1.2315
1.231
Dropout - mV
VO - Output Voltage - V
20
1.2305
1.23
VIN_LDO35 = 3.3 V,
Load = 150 mA,
CO(LDO35) = 1 mF
120
110
1.2295
100
1.229
1.2285
0
20
40
60
80
100
120
140
90
0
TJ - Junction Temperature - °C
40
60
80
100
TJ - Junction Temperature - °C
Figure 12.
24
20
Figure 13.
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120
140
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
TYPICAL CHARACTERISTICS – SM1 AND SM2 BUCK CONVERTERS
Measured with application circuit shown in Figure 3, unless otherwise noted
PWM MODE
EFFICIENCY
vsOUTPUT CURRENT
EFFICIENCY IN AUTOMATIC
PWM/PFM MODE
100
92
90
90
80
70
Efficiency - %
Efficiency - %
88
86
84
82
60
50
40
30
VIN_SM2 = 4.6 V,
VO (SM2) = 1.8 V,
L = 3.3 mH.
CO(SM2) = 10 mF
80
78
20
VIN_SM1 = 4 V,
VO(SM1) = 1.24 V,
10
L = 3.3 mH,
CO(SM1) = 10 mF
0
76
0
0.1
0.2
0.4
0.3
0.5
IO - Output Current - A
0.6
0.7
0
0.1
0.2
0.3
0.4
IO - Output Current - A
0.5
Figure 14.
Figure 15.
PFM OPERATION
PFM LOW RIPPLE OPERATION
AC = 5 V,
VIN_SM2 = 4.6 V,
VO(SM2 = 1.8 V
0.6
AC = 5 V,
VIN_SM2 = 4.6 V,
VO(SM2 = 1.8 V
IO(SM2)
L = 3.3 mF,
CO(SM2) = 10 mF
IO(SM2)
L = 3.3 mF,
CO(SM2) = 10 mF
Figure 16.
Figure 17.
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TYPICAL CHARACTERISTICS – DRIVERS
Measured with application circuit shown in Figure 3, unless otherwise noted
LINE TRANSIENT
LOAD TRANSIENT
VIN_SM2
VO(SM2)
VO_SM2
AC = 5 V, VIN_SM2 = 3 V (DC) + 1 V (AC),
VO(SM2) = 1.8 V, IO(SM2) = 100 mA,
L = 3.3 mF, CO(SM1) = 10 mF,
CH1 = VIN_SM2, CH2 = VO(SM2)
AC = 5 V,
VIN_SM2 = 4 V,
VO(SM2) = 1.8 V,
IO(SM2) = 0 mA to 600 mA,
IO(SM2)
L = 3.3 mF, CO(SM1) = 10 mF,
CH1 = VO_SM2,
CH3 = IO(SM2)
Figure 18.
Figure 19.
TRANSIENT - SM1 STARTUP
TRANSIENT - SM2 STARTUP
AC = 5 V,
VIN_SM2/SM2 = 4 V,
VO(SM2) = 1.8 V,
IO(SM2) = 600 mA,
SM2 Voltage
SM1 Voltage
AC = 5 V,
VIN_SM2/SM2 = 4 V,
VO(SM2) = 1.8 V,
IO(SM2) = 600 mA,
L = 3.3 mF,
CO(SM1) = 10 mF
L = 3.3 mF,
CO(SM1) = 10 mF
SM1 Current
SM2 Current
Figure 20.
26
Figure 21.
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TYPICAL CHARACTERISTICS – DRIVERS (continued)
Measured with application circuit shown in Figure 3, unless otherwise noted
SM3 LED CURRENT
vs
PWM DUTY CYCLE
SM3 WHITE LED DRIVER
SOFT START
BAT = 4 V,
DC = 0%
L3 = 4.7 mF,
CO(SM3) = 10 mF,
CH1 = L3,
CH4 = SM3
BAT = 4 V, DC = 0%
L3 = 4.7 mF, CO(SM3) = 10 mF,
CH1 = L3, CH4 = SM3
Figure 22.
Figure 23.
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SERIAL INTERFACE
Overview
The TPS65800 is compatible with a host-controlled environment, with internal parameters and status information
accessible via an I2C interface. An I2C communication port provides a simple way for an I2C compatible host to
access system status information and reset fault modes, functioning as a SLAVE port enabling I2C compatible
hosts to WRITE to or to READ from internal registers. The TPS65800 I2C port is a 2-wire bidirectional interface
using SCL (clock) and SDA (data) pins; the SDA pin is open drain and requires an external pullup. The I2C is
designed to operate at SCL frequencies up to 400 kHz. The standard 8 bit command is supported, the CMD part
of the sequence is the 8 bit register address to READ from or to WRITE to.
Register Default Values
The internal TPS65800 registers are loaded during the initial power-up from an internal, non-volatile memory
bank. The power-up default values are described in the sections detailing the registers functionality.
The register contents remain intact as long as OUT pin voltage remains above the internal UVLO threshold,
VUVLO When the OUT pin voltage falls below the VUVLO threshold all register bits are reset to the internal power
up default.
I2C Address
The I2C specification contains several global addresses, which the slaves on the bus are required to respond to.
The TPS65800 only responds (ACK) to addresses 0x90 and 0x91 and does not respond (NACK) to any other
address.
Table 1. TPS65800 I2C Read/Write Address
BYTE
TPS65800 I2C WRITE ADDRESS
TPS65800
I2C
READ ADDRESS
I/O DATA BUS
BIT
MSB
6
5
4
3
2
1
LSB
1
0
0
1
0
0
0
0
1
0
0
1
0
0
0
1
B7
B6
B5
B4
B3
B2
B1
B0
Incremental Read
The TPS65800 does not support incremental read operations. Each register must be accessed in a single read
operation.
I2C Bus Release
The TPS65800 I2C engine does not create START or STOP states on the I2C bus during normal operation.
Sleep Mode Operation
When the sleep mode is set SDAT is held LO by the TPS65800. The overall system operation is not affected, as
in sleep mode all TPS65800 integrated supplies are disabled and no power is available for any external devices
connected to the TPS65800 SDAT pin. When sleep mode ends the SDAT pin is released before the TPS65800
integrated regulated supplies are enabled. See section on System Sequencing and TPS65800 Operating Modes
for additional details on sleep mode operation.
I2C Bus Error Recovery
The I2C bus specification does not define a method to be used when recovering from a host side bus error.
During a read operation, the SDA pin can be left in a LO state if the host has not sent enough SCL pulses to
complete a transaction (i.e., host side bus error). The TPS65800 clears any SDA LO condition if 10 SCL pulses
are sent by the host, enabling recovery from host side bus error events.
I2C Communication Protocol
The following conventions are used when describing the communication protocol:
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2
Table 2. I C Naming Conventions Used
CONDITION
CODE
START sent from host
S
STOP sent from host
P
TPS65800 I2C slave address sent from host, bus direction set from host to TPS65800 (WRITE)
hA0
TPS65800 register address sent from TPS65800, bus direction is from TPS65800 to host (READ)
hA1
Non-valid
I2C
slave address sent from host
hA_N
Valid TPS65800 register address sent from host
HCMD
Non-valid TPS65800 register address sent from host
HCMD_N
I/O data byte (8 bits) sent from host to TPS65800
hDATA
I/O data byte (8 bits) sent from TPS65800 to host
bqDATA
Acknowledge (ACK) from host
hA
Not acknowledge (NACK) from host
hN
Acknowledge (ACK) from TPS65800
bqA
Not acknowledge (NACK) from TPS65800
bqN
STOP
CONDITION
(P)
START
CONDITION
(S)
STOP
CONDITION
(P)
START
CONDITION
(S)
BIT 7
MSB
BIT0
LSB
BIT 6
ACKNOWLEDGE STOP
CONDITION
(hA or bqA
)
(P)
SCL
STOP
CONDITION
(P)
START
CONDITION
(S)
BIT 7
MSB
BIT 6
SDA
DATA
CHANGE
ALLOWED
SCL
BIT 7
MSB
BIT 6
BIT 5-1
BIT 0
LSB
NOT
STOP
ACKNOWLEDGE CONDITION
(hN or bqN)
(P)
SDA
DATA LINE
STABLE
SCL
SDA
Figure 24. I2C operation waveforms
For normal data transfers, SDA is allowed to change only when SCL is low, and one clock pulse is used per bit
of data. The SDA line must remain stable whenever the SCL line is high, as SDA changes when SCL is high are
reserved for indicating the start and stop conditions. Each data transfer is initiated with a start condition and
terminated with a stop condition.
When addressed, the TPS65800 device generates an acknowledge bit after the reception of each byte by
pulling the SDA line Low. The master device (microprocessor) must generate an extra clock pulse that is
associated with the acknowledge bit. After the acknowledge/not acknowledge bit the TPS65800 leaves the data
line high, enabling a STOP condition generation.
I2C Read and Write Operations
The TPS65800 supports the standard I2C one byte Write. The basic I2C read protocol has the following steps:
• Host sends a start and sets TPS65800 I2C slave address in write mode.
• TPS65800 ACKs that this is a valid I2C address and that the bus is configured for write.
• Host sends TPS65800 register address.
• TPS65800 ACKs that this is a valid register and stores the register address to be read.
• Host sends a repeated start and TPS65800 I2C slave address, reconfiguring the bus for read.
• TPS65800 ACKs that this is a valid address and that bus is reconfigured.
• Bus is in read mode, TPS65800 starts sending data from selected register.
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The I2C write protocol is similar to the read, without the need for a repeated start and bus being set in write
mode. In a WRITE it is not necessary to end each 1 byte WRITE command with a STOP, a START has the
same effect (repeated start).
SCLK
SDAT
...
A6
...
..
A0
R/W ACK
0
Start
0
Slave Address
hA0
..
R7
...
R0
Register
Address
hCMD
bqA
ACK
A6
..
...
A0
R/W
ACK
1
0
0
bqA
Slave Address
hA1
S
D7
..
D0
Slave
Drives
the Data
bqDATA
bqA
ACK
Master Drives
ACK and Stop
hA
P
Repeated Start, can be replaced by a
STOP and START
...
SCLK
SDAT
Start
A6
A5
...
A4 ...
A0
R/W
ACK
0
0
Slave Address
hA0
R7
bqA
R6
R5
...
...
R0 ACK
D7
0
Register
Address
hCMD
bqA
D6
D5 ...
Host Sends
Data
hDATA
D0 ACK
0
bqA
P
Figure 25. I2C read and write operations
The host can complete a READ or a WRITE sequence with either a STOP or a START.
Valid Write Sequences
The TPS65800 always ACKs its own address. If the CMD points to an allowable READ or WRITE address, bq
writes the address into its RAM address register and sends an ACK. If the CMD points to a non-allowed
address, bq does NOT write the address into its RAM address register and sends an NACK.
S
S
S
hA0
hA0
hA0
bqA
bqA
bqA
hCMD
hCMD_N
bqA
bqN
One Byte Write
The data is written to the addressed register when the bq ACK ending the one byte write sequence is received.
The host can cancel a WRITE by sending a STOP or START before the trailing edge of the bq ACK clock pulse.
S
30
hA0
bqA
hCMD
bqA
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Valid Read Sequences
The TPS65800 always ACKs its own address.
S
hA1
bqA
Upon receiving hA1, TPS65800 starts at wherever the RAM address register is pointing. The START and the
STOP both act as priority interrupts. If the host has been interrupted and is not sure where it left off it can send a
STOP and reset the TPS65800 state machine to the WAIT state; once in WAIT state, the TPS65800 ignores all
activity on the SCL and SDA lines until it receives a START. A repeated START and START in the I2C
specification are both treated as a START.
S
S
S
hA0
hA0
hA1
bqA
bqA
bqA
hCMD
hCMD
bqDATA
bqA
bqA
hN
P
S
P
hA1
bqA
bqDATA
hN
P
Non-Valid Sequences
Incremental read sequences
S
hA1
bqA
bqDATA
hA
bqDATA
hA
bqDATA
hA
bqDATA
hA
...
bqDATA
hA
P
START and non-hA0 or non-hA1 Address
A START followed by an address which is not bqA0 or bqA1 is NACKed.
S
hA_N
bqN
Attempt to Specify Non-Allowed READ Address
If the CMD points to a non-allowed READ address (reserved registers), bq sends a NACK back to the host, and
it does not load the address in the RAM address register. Note that TPS65800 NACKS whether a stop is sent or
not.
S
S
hA0
hA0
bqA
bqA
hCMD_N
hCMD_N
bqN
bqN
P
Attempt to Specify Non-Allowed WRITE Address
If the host attempts to WRITE to a READ-ONLY or non-accessible address TPS65800 ACKS the CMD
containing the allowed READ address, loads the address into the address register and NACKS after the host
sends the next data byte. After issuing the NACK TPS65800 returns to WAIT state. A subsequent hA1 READ
could read this address.
S
hA0
bqA
hCMD
bqA
hDATA
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TPS65800 INTERNAL REGISTER MAP
hex
NAME
DESCRIPTION
ADDITIONAL
DETAILS
0
RESERVED_01
RESERVED
FACTORY ONLY
1
RESERVED_02
RESERVED
FACTORY ONLY
2
PGOOD
Output voltage status for linear regulators and dc/dc buck converters
3
INTMASK1
Interrupt request masking settings
4
INTMASK2
Interrupt request masking settings
5
INT_ACK1
Masked interrupt request register, latched
6
INT_ACK2
Masked interrupt request register, latched
7
PGOODFAULT_MASK
System Reset masking settings
8
SOFT_RESET
Generates a software reset
9
CHG_CONFIG
Battery charger configuration
A
CHG_STAT
Battery charger status
B
EN_LDO
Linear regulator ON/OFF control
C
LDO12
LDO1 and LDO2 output voltage setting
D
LDO3
LDO3 output voltage settings
E
LDO4
LDO4 output voltage settings
F
LDO5
LDO5 output voltage settings
10
SM1_SET1
SM1 Buck converter ON/OFF control and output voltage setting, normal mode
11
SM1_SET2
SM1 Buck converter configuration
12
SM1_STANDBY
SM1 Buck converter standby mode ON/OFF and standby output voltage setting
13
SM2_SET1
SM2 Buck converter ON/OFF control and output voltage setting, normal mode
14
SM2_SET2
SM2 Buck converter configuration
15
SM2_STANDBY
SM2 Buck converter standby mode ON/OFF and standby output voltage setting
16
SM3_SET
SM3 White LED driver ON/OFF control and settings
17
RGB_FLASH
Overall RGB driver timing settings
18
RGB_RED
RGB driver: RED duty cycle and output current setting
19
RGB_GREEN
RGB driver: GREEN duty cycle and output current setting
1A
RGB_BLUE
RGB driver: BLUE duty cycle and output current setting
1B
GPIO12
GPIO1 and GPIO2 configuration
1C
GPIO3
GPIO2 and GPIO3 configuration, battery charge voltage selection
1D
PWM
PWM output configuration
1E
ADC_SET
ADC On/OFF control, ADC configuration
1F
ADC reading_hi
ADC data output
20
ADC reading_lo
ADC data output
21
DHILIM1
ADC Maximum threshold setting
22
DHILIM2
ADC Maximum threshold setting
23
DLOLIM1
ADC Minimum threshold setting
24
DLOLIM2
ADC Minimum threshold setting
25
ADC_DELAY
ADC configuration: conversion delay
26
ADC_WAIT
ADC configuration: wait and repeat operation
27
LED_PWM
LED_PWM configuration
2E
RESERVED_03
RESERVED
32
FACTORY ONLY
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FUNCTIONALITY REFERENCE GUIDE – HOST INTERFACE AND SYSTEM SEQUENCING
INTERRUPT CONTROLLER, OPEN-DRAIN OUTPUT (INT)
System Parameters Monitored by Interrupt Controller
Supply Output
Power Good Fault
Detection (1)
System
Status
Modification
SM1,
SM2,
SM3,
LDO1, LDO2,
LDO3, LDO4,
LDO5
Thermal Fault or
GPIO 1,2
configured as
external interrupt
request
Can be masked Individually
via I2C. Blanked during
initial power up
(1)
Power up
default
Charger Status
Transition
ADC status
Input and Output
Power Transition
Charge: Pre↔ Fast
ADC conversion end
↔Done
AC detected: yes ↔ no
ADC
DPPM:on ↔ off
USB detected: yes ↔ no
Input out of range
Charge Suspend: on ↔
Input OVP: yes ↔ no
External resistive
off
System Power: AC ↔
load connected to
Thermal Foldback: on
USB
ANLG1
↔ off
All interrupt
controller
inputs set to
non-masked
Can be masked as a group via a single I2C mask
register bit
Can be masked Individually via I2C
For all supplies (except) for SM3 an output fault is detected if the output voltage is below 90% of the programmed regulation voltage. In
the SM3 converter an output fault indicates that the output OVP threshold was reached.
EVENTS TRIGGERING TPS65800 OPERATING MODE CHANGES
EVENT
POWER GOOD FAULT
DETECTION (1)
THERMAL
FAULT
HARDWARE
RESET
SOFTWARE
RESET
How transition is
triggered
Integrated regulator output
voltage below target value:
SM1, SM2, SM3, LDO1,
LDO2,LDO3, LDO4, LDO5
Internal IC junction
temperature
Using HOT_RST control
pin
I2C register control bit
Operating mode
change
Sets Sleep mode or starts a
new power-up cycle when
power good fault is detected
(see state machine diagram).
Sets sleep mode when
thermal fault is detected
Generates external host
reset pulse at pin
RESPWON when
HOT_RST=LO.
Generates external host
reset pulse at pin
RESPWON when I2C
control bit is set.
Power good fault detection
Input and battery power
comparators are blanked during cycling required to exit
initial power-up.
sleep
Pulse duration set by
external capacitor.
Pulse duration set by
external capacitor.
Can be masked Individually via
I2C.
External Input
Set via I2C
Controls
100 kW
R4
2 kW
2 kW
R2
R3
100 kW
For all supplies (except) for SM3 an output fault is detected if the output voltage is below 90% of the programmed regulation voltage. In
the SM3 converter an output fault indicates that the output OVP threshold was reached.
R5
(1)
Fixed internal threshold
TPS65800
HOST INTERFACE
AND SEQUENCING
SCLK
I2C ENGINE
SDAT
INTERRUPT
CONTROLLER
INT
HOST
RESPWRON
TRSTPWON
CTRSTPWON
STATE MACHINE
AND RESET
CONTROLLER
HOT_RST
0.1 mF
SYS_IN
OUT
A1
R6
R1
210 kW
C16
100 nF
100 kW
A1
A1
Figure 26. Required External Components, Recommended Values, External Connections
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INTERRUPT CONTROLLER AND SYSTEM SEQUENCING
Overview
The TPS65800 has two dedicated internal controllers that execute the host interface and system sequencing
tasks: a sequencing controller and an interrupt controller.
The sequencing controller monitors internal and system parameters and defines the sequencing of the internal
power supplies during power up and power down / power fault events, and executes specific internal power
supply reset operations under external hardware control or host software commands.
The following parameters are monitored by the sequencing controller:
• System power bus voltage (at SYS_IN pin), input supply voltage, battery pack voltage
• TPS65800 thermal fault status
• Integrated supply status
The interrupt controller monitors multiple system status parameters and signals to the host when one of the
monitored parameters toggled, as a result of a system status change. The interrupt controller inputs include all
the parameters monitored by the sequencing controller plus:
• Charger status
• Battery pack status
• ADC status
Internal I2C registers enable masking of all the monitored parameters. Using those registers the host can select
which parameters trigger an interrupt or a power-good fault. Power good faults trigger a change in the
TPS65800 operating mode, as detailed in the next sections.
TPS65800
HOST INTERFACE AND SEQUENCING
R4
R2
R3
R5
A simplified block diagram for the TPS65800 sections that interface to the external host is shown in Figure 27.
SCLK
SDAT
INT
I 2C ENGINE
INTERRUPT
CONTROLLER
2.5 V
I2C REGISTERS
AND
NON-VOLATILE
MEMORY
AC/USB/BAT
(HIGHER VOLTAGE)
2.5 V
HOST
RESPWRON
TRSTPWON
CTRSTPWON
SEQUENCING
AND OPERATING
MODE SETTING
VSYS
CONTROL
LOGIC
1V
HOT_ RST
SYS _IN
A1
OUT
R1
R6
C 16
A1
Figure 27. Simplified Block Diagram
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SYSTEM SEQUENCING AND TPS65800 OPERATING MODES
The TPS65800 has a state machine that controls the device power up and power down sequencing. The main
operating modes are shown in the state diagram below:
POWER UP
LOAD POWER UP DEFAULTS IN
I2C REGISTERS
CONNECT AC , USB OR BAT PIN TO
OUT PIN
V(AC) > VUVLO DISABLE POWER GOOD FAULT
OR
DETECTION
V(USB) > VUVLO
INT PIN = HIGH IMPEDANCE
OR
POR_FLAG= HI
V(BAT ) > VUVLO
OFF
V(OUT) < VUVLO
ANY
STATE
ENABLE STATE
V(SYS_IN) < V(LOW_SYS)
OR
THERMAL
FAULT
OR
I2C SOFT_RESET
REGISTER
BIT SLEEP_MODE = HI
(SELF-CLEARED)
RESPWRON=LO,
START BOOT - UP TIMER
V(SYS_IN) > V(LOW_SYS) AND
V(OUT) > VUVLO
POWER
CYCLE
AND
SLEEP NOT SET BY
THERMAL FAULT
SEQUENCE STATE
START INTEGRATED
SUPPLY START - UP SEQUENCE
RESPWRON = LO
V(HOT_RESET)=HI OR
I2C SOFT_RESET
REGISTER BIT
SOFT_RESET = LO
(SELF CLEARED )
SLEEP STATE
ONLY RTC_LDO IS ON
POWER PATH ACTIVE
RESPWRON = 0
REGISTER CONTENTS NOT RESET
INTERRUPT CLEARED
PGOOD
FAULT
RESET STATE
RESET
TIMER EXPIRES
POWER GOOD
CHECK STATE
PGOOD FAULT : A NON- MASKED BIT OF THE
POWER _GOOD I2C REGISTER TOGGLES
FROM LO TO HI
STANDBY ON : SM1 AND SM2 SET IN STANDBY
MODE BY GPIO OR I 2C COMMAND
STANDBY OFF : SM1 AND SM2 EXIT STANDBY
MODE BY GPIO OR I2C COMMAND
RESET TIMER : VALUE SET BY CAPACITOR
CONNECTED TO TRSTPWON PIN
I2C SOFT_RESET BIT LOCATED IN
SOFT_RESET REGISTER , BIT B0
RESPWRON=LO
RESPWRON=LO
START SYSTEM RESET PULSE TIMER
WHEN HOT_RESET=HI
V(HOT_RESET)=LO
OR
I2C SOFT_RESET
REGISTER BIT
SOFT_RST= HI
PROCESSOR
STANDBY STATE
RESPWRON = HI
PG FOR SM1&SM2
is masked
RESPWRON=HI
ENABLE POWER GOOD COMPARATORS
INT PIN MODE SET BY INTERRUPT
CONTROLLER
NO PGOOD
FAULT
V(HOT_RESET)=LO
OR
I2C SOFT_RESET
REGISTER BIT
SOFT_RST = HI
STANDBY
ON
STANDBY
OFF
NORMAL MODE
RESPWRON=HI
PGOOD
FAULT
Figure 28. TPS65800 State Diagram
POWER-UP– If the AC, USB and BAT pin voltages are below the internal UVLO threshold VUVLO (2.5 V typ) all
IC blocks are disabled and the TPS65800 is not operational, with all functions OFF. When an external power
source or battery with voltage greater than the VUVLO voltage threshold is applied to AC/USB or BAT pins the
internal TPS65800 references are powered up, biasing internal circuits. When all the main internal supply rails
are active the TPS65800 I2C registers are set to the power-up default values, shown below:
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Table 3. Integrated Supply and Drivers Power-Up Defaults
SUPPLY
POWER-UP DEFAULT
OTHER BLOCKS
POWER-UP DEFAULT
LDO0
OFF, 3.3 V
POWER PATH
INPUT TO SYSTEM
LDO1
2.85V, ON
PWM
OFF
LDO2
3.3 V, ON
PWM_LED
OFF
LDO3
1.25 V, ON
GPIO1
INPUT
LDO4
2.75 V, ON
GPIO2
INPUT
LD05
2.81 V, ON
GPIO3
INPUT
SIM
1.8 V, OFF
ADC
OFF
RTC_OUT
ON, 3.1 V
SM3 (WHITE LED)
OFF
LDO_PM
3.3 V, ON @ OUT POWERED
RGB DRIVER
OFF
SM1
ON, 1.24 V
INTERRUPT MASK
NONE MASKED
SM2
ON, 1.8 V
POWER GOOD MASK
ALL MASKED
CHARGER
ON
After the internal I2C register power-up defaults are loaded the power path control logic is enabled, connecting
the external power source to the OUT pin. A status flag (nRAMLOAD) is set to LO in the SOFT_RESET register,
indicating that the I2C registers were loaded with the power-up defaults, and the TPS65800 enters the ENABLE
mode.
ENABLE: In the ENABLE mode the RESPWRON output is set to the LO level, the INT pin mode is set to high
impedance and all the power good comparators that monitor the integrated supply outputs are disabled. The
ENABLE mode is used by the TPS65800 to detect when the main system power rail (OUT pin) is powered and
ready to be used on the internal supply power-up. The OUT pin voltage is sensed by an internal low system
voltage comparator, which holds the IC in the ENABLE mode until the system power bus voltage (OUT pin) has
reached a minimum operating voltage, defined by the user. The internal comparator senses the system voltage
at pin SYS_IN, and the threshold for the minimum system operating voltage at the OUT pin is set by the external
divider connected from OUT pin to SYS_IN pin. The threshold voltage is calculated as follows:
V(OUT) + V (LOW_SYS)
1 ) R6 :
R1
where R6 and R1 are external resistors, V (LOW_SYS) + 1 V typical
(1)
ǒ
Ǔ
The minimum system operating voltage should always be set above the internal UVLO threshold VUVLO. In
normal application conditions the minimum system operating voltage is usually set to a value that assures that
the TPS65800 integrated regulators are not operating in the dropout region.
When the voltage at the SYS_IN pin exceeds the internal threshold V(LOW_SYS) the TPS65800 is ready to start
the system power sequencing, and the SEQUENCING mode is entered.
SEQUENCING– The sequencing state starts immediately after the enable state. In this mode of operation the
integrated supplies are turned ON, according to the sequencing steps loaded from the internal non-volatile
memory during the power-up phase. The TPS65800 sequencing timing diagram shown in figure details the
internal timing delays and supply sequencing. At the end of the sequencing state the user-programmable reset
timer is started, and the TPS65800 enters the reset state.
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Power Applied
AC, USB, OR BAT
VUVLO
OUT
VUVLO
SYS_IN
VLOW_SYS
RTC_OUT
LDO1
LDO2
LD04
LDO5
LDO3
SM1
SM2
INT
HI-Z
HI-Z
HI-Z
RESPWRON
tDLY(D1)
tDLY(D2)
RESET DELAY
PROGRAMMED BY EXTERNAL CAPACITOR
CONNECTED TO PIN TRSTPWON
NO POWER
SEQUENCING
ENABLE
RESET
NORMAL
2
I C Registers Loaded From
2
E PROM
Figure 29. TPS65800 Supply Sequencing Timing
RESET – When the reset state starts the RESPWRON output is LO. The user can program the reset timer value
selecting the value of the external capacitor connected to pin TRSTPWON, as shown below:
T(RESET) = KRESET× CTRSTPWON; where KRESET is the reset timer constant (1 ms/nF typ)
The TPS65800 RESPWRON pin should be used to reset the external host. During the external host reset
(RESPWRON = LO) the I2C SDA and SCL pins are not used to access TPS65800 internal registers. If a
non-standard configuration is used to reset the system the SDA and SCL lines should not be used to
communicate with the TPS65800 until RESPWRON = HI, in order to avoid overwriting the integrated power
supply internal power-up settings during the sequencing mode.
The power good comparators are masked during the reset mode. The reset mode ends when the reset timer
expires, and the TPS65800 goes into the power good check mode.
The RESPWRON signal set to a high level is the proper signal to use as an indicator that the device has
transitioned out of the reset state. During the power-up sequence the RESPWRON pin is asserted LOW until the
RESET TIMER expires. The RESET TIME (treset = 1ms/nF × CTRSTPWON) can be programmed via a capacitor
between the TRSTPWON pin and ground.
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When the RESPWRON signal is LO, all internal and external interrupts are ignored. As a result, the open-drain
output that asserts the INT pin LO during a NORMAL MODE interrupt request is disabled. The INT pin is then
asserted HI via a pullup resistor that is typically connected to VOUT. After the RESPWRON signal goes HI, the
interrupt controller is given control of the INT pin. Finally, the rising edge of the RESPWRON pin should be used
to indicate the PMIC has transitioned from the RESET STATE to the POWER GOOD CHECK STATE. At that
point, the interrupt controller asserts an interrupt if necessary.
POWER GOOD CHECK – In the power good check mode the power good comparators are enabled, providing
status on the integrated supplies output voltages. An output voltage is considered as out of regulation and
generates a fault condition if the output voltage is below 90% of the target output voltage regulation value. If a
power good fault is detected the SLEEP mode is set, if a power good fault is not detected the NORMAL mode is
set.
The individual supply power good status can be masked via an I2C register PGOODFAULT_MASK. Supplies
that have their power-good fault status masked do not generate a power good fault. However, the status bit for
the supply indicates that the output voltage is out of regulation.
The power good mask register bits default to masked upon power up.
NORMAL MODE – If a power good fault is not present at the end of the power good check mode the NORMAL
mode starts. In this mode of operation the I2C registers define the TPS65800 operation, and the host has full
control on operation modes, parameter settings, etc. The normal state operation ends if a thermal fault, system
low voltage fault ( V(SYS_IN) < VLOW_SYS ) or power-good fault is detected. A thermal fault or system low voltage
fault sets the SLEEP mode operation, a power good fault sets the NO POWER operation mode. From the
normal mode the converters SM1 and SM2 can be set in the STANDBY mode, with reduced output voltages. In
NORMAL mode either an I2C register bit (SOFT_RESET register bit SOFT_RST) or a hardware input (
HOT_RESET pin set to LO) can trigger a transition to the RESET state, enabling implementation of a host reset
function. In NORMAL mode an I2C register bit (SOFT_RESET register bit SLEEP_MODE) can trigger a
transition to SLEEP mode.
SLEEP MODE – The SLEEP mode is set when a thermal fault or system low voltage fault is detected, under
NORMAL operation mode set. This operation mode is also set when a power good fault is detected during the
power good check state or via the I2C bit SLEEP_MODE. In the SLEEP mode the RESPWRON output is set to
LO, and the I2C registers keep the same contents as in the state preceding SLEEP mode, with the exception of
the following control bits, which are reset to the default power-up values:
1. LDO1, -2, -3, -4, -5, and RTC_OUT are enabled, SIM LDO is disabled: EN_LDO register set to default
values
2. LDO0 disabled, all GPIO’s with no control function assigned: GPIO12, GPIO3 registers set to default
values
3. White LED driver is set to OFF: SM3_SET register has all bits set to LO
4. RGB drivers are set to OFF: RGB_FLASH, RGB_RED, RGB_GREEN, RGB_BLUE registers are set to
default values
5. PWM, PWM_LED drivers OFF: PWM, LED_PWM registers are set to default values
6. ADC engine reset to power up default: ADC_SET, ADC_DELAY, ADC_WAIT registers are set to default
values
In SLEEP mode, the power path and main internal blocks are still active, but the internal integrated
supply sequencing is disabled. As a result of that, during SLEEP mode ALL integrated supplies (ALL
LDOs, ALL buck converters) are disabled.
At the end of the SLEEP mode, the sequencer block uses the I2C control register values (which were reset to
the default power-up values) to sequence the integrated power supplies. The SLEEP mode ends when one of
the three following events happens:
1. If SLEEP was set by thermal fault: The SLEEP mode ends only when all external input supplies and
battery pack are removed and a UVLO condition is detected by the TPS65800, setting the NO POWER
mode.
2. If SLEEP was set by a system low voltage detection, or I2C bit SLEEP_MODE, only with battery present:
Input power must be connected, setting the TPS65800 in the ENABLE mode. If no input power is
inserted, the battery discharges until the TPS65800 detects an UVLO condition and enters the NO
POWER mode.
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3. If sleep was set by a system low-voltage detection, power good fault or SLEEP_MODE, with battery and
input power present: all external input supplies connected to AC and USB pins must be removed, and
then at least one of them reconnected to the system. The input power cycling triggers a transition from
the SLEEP mode to the ENABLE mode.
PROCESSOR STANDBY STATE– This state is set using a I2C register or a GPIO configured as SM1/SM2
standby control. In standby mode operation the SM1 and SM2 voltages are set to value distinct than the normal
mode output voltage, and SM1/SM2 are set to PFM mode. The standby output voltage is defined in I2C registers
SM1_STANDBY and SM2_STANDBY.
TPS65800 OPERATING MODE CONTROLS
HARDWARE RESET: A dedicated control pin, HOT_RESET, enables implementation of a hardware reset
function. The system reset pin RESPWRON is set to LO when HOT_RESET = LO for a period longer than the
internal deglitch (5 ms, typ). The RESET mode is started when the HOT_RESET pin transitions from LO to HI,
as shown in the state diagram.
SOFTWARE RESET: The external host can set the TPS65800 in RESET mode using the I2C register
SOFT_RESET, bit B0 (SOFT_RST).
SOFTWARE SLEEP: The external host can set the TPS65800 in SLEEP mode using the I2C register
SOFT_RESET, bit B6 (SLEEP_MODE).
A hardware or software reset does not affect the contents of the I2C registers.
SEQUENCING AND OPERATING MODES – I2C REGISTERS
The I2C registers that control sequencing-related functions are shown below. The HEX address for each register
is shown by the register name, together with the R or W functionality for the register bits. Shaded values indicate
default initial power-up values.
SOFT_RESET, ADDRESS=08, ALL BITS R/W, BITS B7/B6/B1/B0 APPLY TO SEQUENCING.
B7
B6
B5
B4
B3
B2
B1
B0
Bit name
STBY MODE
SLEEP MODE
NOT USED
NOT USED
SM3_LF_OSc
NOT USED
nRAMLOAD
SOFT RST
Function
SET SM1 AND
SM2 IN
STANDBY
MODE
SET TPS65800
IN SLEEP
MODE
NOT USED
NOT USED
NOT USED
RAM RESET
FLAG
SOFTWARE
RESET
CONTROL
When 0
NOT ACTIVE
NOT ACTIVE
NOT USED
NOT USED
NOT RELATED
TO
SEQUENCING
SEE SM3
SECTION
NOT USED
RAM
DEFAULTS
LOADED
NOT ACTIVE
When 1
When 1 SET
SM1 AND SM2
IN STANDBY
SET SLEEP
MODE (reset to
LO internally)
NOT USED
NOT USED
NOT USED
RAM
DEFAULTS
NOT LOADED
SET RESET
MODE (reset to
LO internally)
Some host algorithms need to identify when the power-up defaults are loaded in the RAM, in order to start
routines that initialize specific RAM registers. If that functionality is required the nRAMLOAD bit should be set to
HI by the host when entering hte NORMAL operation mode. The nRAMLOAD bit is reset to LO by the
TPS65800 when the power-up defaults are loaded in the I2C registers (V(OUT)<VUVLO OR PGOOD fault
detected), enabling the host algorithm to detect that the RAM registers require initialization.
The integrated supplies status is available in a dedicated register, shown below. The host can select which
integrated supply outputs trigger a power-good fault condition using the PGOODFAULT_MASK register.
When a non-masked power-good status register bit toggles state, the sequence controller generates a transition
in the TPS65800 state machine, indicated as a PGOOD FAULT in the TPS65800 state diagram.
The power-good status register and mask register are shown below:
SYSTEM STATUS MONITORED BY SEQUENCING CONTROLLER
B7
B6
B5
B4
B3
B2
B1
B0
PGOOD, ADDRESS=02, ALL BITS READ ONLY - POWER UP DEFAULTS SHOW SYSTEM STATUS WHEN EXITING POWER DOWN
Bit name
PGOOD SM1
PGOOD SM2
PGOOD SM3
Function
SM1 OUTPUT
STATUS
SM2
OUTPUT
STATUS
SM3 OVP
STATUS
PGOOD LDO1
PGOOD LDO2
PGOOD LDO3
PGOOD LDO4
PGOOD LDO5
LDO1 OUTPUT LDO2 OUTPUT LDO3 OUTPUT LDO4 OUTPUT LDO5 OUTPUT
STATUS
STATUS
STATUS
STATUS
STATUS
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SYSTEM STATUS MONITORED BY SEQUENCING CONTROLLER
B7
B6
B5
B4
B3
B2
B1
B0
When 0
OK
OK
OK
OK
OK
OK
OK
OK
When 1
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
PGOODFAULT_MASK, ADDRESS=07, ALL BITS R/W
Bit name
MASK_PSM1
MASK_PSM2
MASK_PSM3
MASK_PLDO1
MASK_PLDO2
MASK_PLDO3
MASK_PLDO4
MASK_PLDO5
Function
MASK PGOOD
FAULT BY SM1
MASK
PGOOD
FAULT BY
SM2
MASK PGOOD
FAULT BY
SM3
MASK PGOOD
FAULT BY
LDO1
MASK PGOOD
FAULT BY
LDO2
MASK PGOOD
FAULT BY
LDO3
MASK PGOOD
FAULT BY
LDO4
MASK PGOOD
FAULT BY
LDO5
When 0
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
When 1
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
INTERRUPT CONTROLLER
The TPS65800 has internal block and overall system status information stored in I2C status registers. The
following subsystems and system parameters are monitored:
• External power supply status: AC or USB supply detected, AC or USB connected to system, AC/USB OVP
• Charger status: on/off/suspend, fast charge/precharge, termination detected, DPPM on, thermal loop ON
• Battery pack status: temperature, discharge on/off
• TPS65800 Thermal shutdown
• ADC status: conversion status, input out of range, ANLG1 high impedance detection
• Integrated supplies status: output out of regulation (power good fault)
The GPIO1 and GPIO2 pins can be configured as inputs, generating an interrupt request to the host (
INT:HI→LO) at the GPIO rising or falling edge. The host can use internal the INT_MASK I2C registers to define
which of the monitored status variables triggers an interrupt. When a non-masked system status bit toggles
state, the interrupt controller issues an interrupt, following the steps below:
1. system status bits that caused the interruption are set to HI in registers INT_ACK1 and INT_ACK2
2. An interrupt is sent to the host ( INT:HI→LO)
Once an interrupt is sent to the host, INT is kept in the LO state and the INT_ACK registers contents are
latched, holding the system status that generated the currently issued interrupt request. When an interrupt
request is active (INT = LO) additional changes in non-masked status registers and control signals are ignored,
and the INT_ACK registers are not updated.
The host must write a 0 to the INT_ACK register bit that generated the interrupt in order to set INT = HI and
enable new updates to the INT_ACK registers. If the host stops in the middle of a WRITE or READ operation,
the INT pin stays at the LO level. The TPS65800 has no reset timeout; it is assumed that the host does not
leave INT = LO and the status registers unread for a long time.
The non-masked I2C register bits and internal control signals generate a new interrupt only after INT is set to HI.
The non-masked power-good fault register bits generate a power-good fault when any of the non-masked bits
detects that the monitored output voltage is out of regulation, independently of the INT pin level.
SYSTEM STATUS — I2C REGISTERS
The I2C registers that have system status data are shown below. The HEX address for each register is shown
by the register name, together with the R or W functionality for the register bits. Those registers are valid, after
an initial power up, when the TPS65800 enters the normal operation mode.
SYSTEM STATUS MONITORED BY INTERRUPT CONTROLLER
B7
B6
B5
B4
B3
B2
B1
B0
PGOOD, ADDRESS=02, ALL BITS READ ONLY - POWER UP DEFAULTS SHOW SYSTEM STATUS WHEN EXITING POWER DOWN
Bit name
PGOOD SM1
PGOOD SM2
PGOOD SM3
Function
SM1 OUTPUT
STATUS
SM2 OUTPUT
STATUS
SM3 OVP
STATUS
PGOOD LDO1
PGOOD LDO2
PGOOD LDO3
PGOOD LDO4
PGOOD LDO5
LDO1 OUTPUT LDO2 OUTPUT LDO3 OUTPUT LDO4 OUTPUT LDO5 OUTPUT
STATUS
STATUS
STATUS
STATUS
STATUS
When 0
OK
OK
OK
OK
OK
OK
OK
OK
When 1
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
FAULT
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SYSTEM STATUS MONITORED BY INTERRUPT CONTROLLER
B7
B6
B5
B4
B3
B2
B1
B0
CHG_STAT, ADDRESS=A, ALL BITS READ ONLY – POWER UP DEFAULTS SHOW SYSTEM STATUS WHEN EXITING POWER DOWN
Bit name
BAT_STAT (1)
INPUT _PWR
THDPPM_ON
ACPG
USBPG
Function
BATTERY DISCH
STATUS
SELECTED
INPUT POWER
STATUS
THERMAL
FAULT AND
DPPM MODE
AC INPUT
POWER
STATUS
USB INPUT
POWER
STATUS
CHARGE STATUS
AC OR USB
INPUT OVP
DETECTION
When 0
NOT
DISCHARGING
AC INPUT
SELECTED
BOTH OFF
AC NOT
DETECTED
USB NOT
DETECTED
NO OVP
When 1
When 1
DISCHARGING
USB INPUT
SELECTED
DPPM ON OR
THERMAL ON
AC DETECTED
USB
DETECTED
00=FAULT/OFF/SUSPEND,
01=DONE, 10=FAST CHG ON,
11= PRECHARGE
STAT1
STAT2
INP_OV
OVP
DETECTED
ADC STATUS
REGISTER ADC_READING_HI, B7: CONVERSION COMPLETE;
INTERNAL STATUS BITS (NO I2C REGISTER BIT AVAILABLE: INPUT OUT OF RANGE (HI OR LO), ANLG1 PIN IMPEDANCE TO AGND2 EXCEEDS 1
mΩ
OTHER SYSTEM STATUS: THERMAL FAULT DETECTED
(1)
BAT_STAT pin does not generate an interrupt, in order to avoid oscillatory behavior when battery supplement mode is set.
INTERRUPT CONTROLLER – I2C REGISTERS
The I2C registers that control an interrupt generation (INT: HI→LO) are shown below. The HEX address for each
register is shown by the register name, together with the R or W functionality for the register bits. Shaded values
indicate default initial power-up values.
INTERRUPT AND POWER GOOD FAULT MANAGEMENT REGISTERS
B7
B6
B5
B4
B3
B2
B1
B0
INTMASK1, ADDRESS=03, ALL BITS R/W
Bit name
MASK_ISM1
MASK_ISM2
MASK_ISM3
MASK_ILDO1
MASK_ILDO2
MASK_ILDO3
MASK_ILDO4
MASK_ILDO5
Function
MASK INT by
SM1 PGOOD
FAULT
MASK INT by
SM2 PGOOD
FAULT
MASK INT by
SM3 PGOOD
FAULT
MASK INT by
LDO1 PGOOD
FAULT
MASK INT by
LDO2 PGOOD
FAULT
Mask INT by
LDO3 PGOOD
FAULT
MASK INT by
LDO4 PGOOD
FAULT
MASK INT by
LDO5 PGOOD
FAULT
When 0
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
When 1
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASK_IGPIO2
MASK_IGPIO1
MASK_ITHSH
UT
MASK_ICHGS
T
INTMASK2, ADDRESS=04, ALL BITS R/W
Bit name
Function
MASK_IADC
MASK_IANLG1
MASKS INT BY MASKS INT BY MASKS INT BY MASKS INT BY MASKS INT BY
ADC END OF
ANLG1 HIGH
GPIO2 EDGE
GPIO1 EDGE
THERMAL
CONVERSION
IMPEDANCE
TRANSITION
TRANSITION
FAULT
MASK_IADC_H MASK_IADC_L
I
O
MASK INT BY
CHG_STAT
REGISTER
BITS
MASK INT BY
ADC INPUT
ABOVE HI
LIMIT
MASK INT BY
ADC INPUT
BELOW LO
LIMIT
When 0
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
When 1
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
INT_ACK1, ADDRESS=05, ALL BITS R/W
Bit name
ACK_SM1
ACK_SM2
ACK_SM3
ACK_LDO1
ACK_LDO2
ACK_LDO3
ACK_LDO4
ACK_LDO5
Function
SM1 INT
REQUEST
SM2 INT
REQUEST
SM3 INT
REQUEST
LDO1 INT
REQUEST
LDO2 INT
REQUEST
LDO3 INT
REQUEST
LDO4 INT
REQUEST
LDO5 INT
REQUEST
When 0
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
When 1
SM1 PGOOD
FAULT
GENERATED
INT
SM2 PGOOD
FAULT
GENERATED
INT
SM3 OVP
FAULT
GENERATED
INT
LDO1 PGOOD
FAULT
GENERATED
INT
LDO2 PGOOD
FAULT
GENERATED
INT
LDO3 PGOOD
FAULT
GENERATED
INT
LDO4 PGOOD
FAULT
GENERATED
INT
LDO5 PGOOD
FAULT
GENERATED
INT
INT_ACK2, ADDRESS=06, ALL BITS READ ONLY
Bit name
ACK_ADC
ACK_ANLG1
ACK_GPIO2
ACK_GPIO1
ACK_THSHUT
ACK_CHGSTA
T
ACK_ADC_HI
ACK_ADC_LO
Function
ADC INT
REQUEST 1
ANLG1
COMPARATO
R INT
REQUEST
GPIO2 INT
REQUEST
GPIO1 INT
REQUEST
THERMAL
FAULT INT
REQUEST
CHARGER INT
REQUEST
ADC INT
REQUEST 2
ADC INT
REQUEST 3
When 0
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
CLEAR FLAG
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INTERRUPT AND POWER GOOD FAULT MANAGEMENT REGISTERS
When 1
B7
B6
B5
B4
B3
B2
B1
B0
ADC DONE
GENERATED
INT REQUEST
ANLG1 HIGH
IMPEDANCE
DETECTION
GENERATED
INT REQUEST
GPIO2 EDGE
GENERATED
INT REQUEST
GPIO1 EDGE
GENERATED
INT REQUEST
THERMAL
FAULT
GENERATED
INT REQUEST
CHARGER
STATUS
CHANGE
GENERATED
INT REQUEST
ADC INPUT
ABOVE HI
LIMIT
GENERATED
INT REQUEST
ADC INPUT
BELOW LO
LIMIT
GENERATED
INT REQUEST
PGOODFAULT_MASK, ADDRESS=07, ALL BITS R/W
Bit name
PGOOD SM1
PGOOD SM2
PGOOD SM3
PGOOD LDO1
PGOOD LDO2
PGOOD LDO3
PGOOD LDO4
PGOOD LDO5
Function
MASK PGOOD
FAULT BY
SM1
MASK PGOOD
FAULT BY
SM2
MASK PGOOD
FAULT BY
SM3
MASK PGOOD
FAULT BY
LDO1
MASK PGOOD
FAULT BY
LDO2
MASK PGOOD
FAULT BY
LDO3
MASK PGOOD
FAULT BY
LDO4
MASK PGOOD
FAULT BY
LDO5
When 0
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
UNMASKED
When 1
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
MASKED
FUNCTIONALITY GUIDE — SYSTEM POWER AND CHARGE MANAGEMENT
CHARGE MANAGEMENT
Fast Charge (1)
Charge
Current Value
Charge Current
Scaling
IO(BAT),
Programmable,
1.5A max
25%, 50%, 75%,
100% of IO(BAT)
Set via external
resistor
Set via I2C
(1)
Precharge
Current
Termination
Charge
Voltage
Precharge
Voltage
SafetyTimer
Timeout
Power Up
Default
25%, 50%, 75%,
100% of I(TERM)
value
4.2 V or
4.36 V
3.0 V
Programmable
Charger ON
Set via I2C
Set via I2C
Fixed
Set via external
resistor
Current
Current Scaling
10% of
IO(BAT)
I(TERM), 10% of
IO(BAT)
Fixed ratio
Fixed ratio
The input current limit (see system power management below ) regulates the input current, effectively limiting the charge current if the
input current limit is lower than the fast charge current value programmed.
POWER PATH MANAGEMENT
INPUT CURRENT LIMIT
AC PIN
2.5 A typ
INPUT CONNECTED TO OUT PIN
POWER UP DEFAULT
USB PIN
INPUT POWER TO SYSTEM
BATTERY TO SYSTEM
100 mA max or
500 mA max or
2.5 A typ
#1 – AC
#2 – USB
#3 – Battery (when AC pin power and USB pin power are
not detected )
Battery connected to
system, independently of
battery voltage
Internal fixed
current limit
Set via I2C
Automatic internal algorithm
Set via I2C, overrides
internal algorithm
TPS 65800
AC _DC Adapter
Output
AC
AC SWITCH
SYSTEM POWER BUS
OUT
OUT
USB Power
C1
10 mF
USB
USB SWITCH
C26
22 mF
BATTERY
SWITCH
C2
10 mF
A1
Battery
BAT
BAT
A1
Input Power to System,
USB mode selected,
100 mA max
A1
POWER PATH
CONTROL
LINEAR
CHARGER
TS
DPPM
TMR
ISET1
C25
10 mF
RSET
1 kW
System Power
Selection
Input Current Limit
Selection
Charge Voltage
Fast Charge
Current Scaling
Charge Suspend
I2C REGISTERS
+
C24
0.22 mF
RTMR
49.9 kW
RDPPM
37.4 kW
50 kW
NTC
C23
47 nF
GND
A1
With the above components the following system
parameters are set :
Fast Charge Current = 1A (100% scaling, input limit=2. 5A)
Safety Timer = 5hours, 30 min pre-charge
DPPM threshold = 4. 3V
Temp hot: 65C
Temp Cold : 5C
Figure 30. Required External Components, Recommended Values, External Connections
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POWER PATH AND CHARGE MANAGEMENT
Overview
The TPS65800 has an integrated charger with power path integrated MOSFETs. This topology, shown in the
simplified block diagram below, enables using an external input power to run the system and charge the battery
simultaneously. The power path has dual inputs that can be used to select either an external AC_DC adapter
(AC pin) or an USB port power (USB pin) to power the end equipment main power rail (OUT pin, also referred to
as the system power bus) and charge the battery pack (connected to BAT pin).
OUTSHORT
500Ω
AC
OUT
I(AC)
AC SWITCH
OUTSHORT
I(AC) / K INTAC
BATSHORT
500
I(USB)
USB SWITCH
AC Control Loops
I(USB) / K INTUSB
V(OUT)
1 kΩ
USB
ACOFF
BATOFF
VO(REG)
System Voltage
Regulation Loop
USBOFF
BATTERY
SWITCH
I (BAT )
AC Input Current
Limit Loop
V (ACOC)
V(USB1)
V(USB2)
BAT
USB Control Loops
BAT
DISCHARGE
CIRCUIT
USB Input Current
Limit Loop
INPUT_LIM
V(OUT)
I(OUT) / K (SET)
VO(REG)
System Voltage
Regulation Loop
ISET1
V(ISET1)
V (SET)
V(BAT)
Charge
Current
Loop
SCALING
CHMODE
DPPM
Charge Voltage
Loop
V (PRECHG)
VREF
V O(REG)
V (DPPM)
ATTENUATION
TJ
DPPM
Loop
VREF
Charger Control Loops
TMR
VREF
Dynamically
Controlled
Oscillator
Timer Fault
TJ(REG)
Thermal
Loop
CONTROL SIGNALS
On, Reset
CHARGE
CONTROL AND
POWER PATH
MANAGEMENT
TS
BAT
ISET1
BATTERY
STATUS
DETECTION
BATTERY
STATUS
CE
CHG_UVLO
LATCH
SYSTEM
STATUS
SYSTEM
STATUS
DETECTION
USB
AC
OUT
CE
System Power
Selection
Input Current Limit
Selection
I2C
REGISTERS
Charger Status
Input Power Status
Charge Voltage
Fast Charge
Current Scaling
Charge Suspend
TPS65800
Figure 31. TPS65800 Charger and Power Path Section Simplified Block Diagram
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The power path has three integrated power MOSFETs: the battery to system MOSFET (battery switch), the AC
input to system MOSFET (AC switch) and the USB input to system MOSFET (USB switch). Each of those power
MOSFETs can be operated either as an ON/OFF switch or as a linear pass element under distinct operating
conditions, as defined by the control circuits that set the power MOSFET gate voltage.
The TPS65800 regulates the voltage at the OUT pin to 4.6 V when one of the external supplies connected to
pins AC or USB is powering the OUT pin. The selected input (AC or USB pin) current is limited to a value
defined by I2C register settings. The input current limit function assures compatibility with USB standard
requirements, and also implements a protection function by limiting the maximum current supplied by an external
AC_DC adapter or USB port power terminal.
The AC power MOSFET and USB power MOSFET operating modes are set by integrated control loops. Each of
the power MOSFETs is controlled by two loops: one system voltage regulation loop and one input current
limiting loop. The integrated loops modulate the AC or USB power MOSFETs drain to source resistance to
regulate either the OUT pin voltage or to limit the input current. If no input power is present (AC and USB input
power not detected) the AC and USB power MOSFETs are turned OFF, and the battery MOSFET is turned ON,
connecting the BAT pin to the OUT pin.
The battery switch is turned ON when the AC or USB input power is detected and the charger function is
enabled, charging the battery pack. During charge the battery MOSFET switch operation mode is defined by the
charger control loops. The battery MOSFET switch drain-to-source resistance is modulated by the charge
current loop and charge voltage loop in order to implement the battery charging algorithm. In addition ot that
multiple safety functions are activated (thermal shutdown, safety timers, short circuit recovery), and additional
functions (thermal loop and DPPM loop) optimize the charging process.
POWER PATH MANAGEMENT FUNCTION
Detecting the System Status
The power path and charge management block operate independently of the other TPS65800 circuits. Internal
circuits check battery parameters (pack temperature, battery voltage, charge current) and system parameters
(AC and USB voltage, battery voltage detection), setting the power path MOSFETs operating modes
automatically. The TPS65800 has integrated comparators that monitor the battery voltage, AC pin voltage, USB
pin voltage and the OUT pin voltage. The data generated by those comparators is used by the power path
control logic to define which of the integrated power path switches is active. A simplified block diagram for the
system status detection is shown below.
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AC
AC DETECTED
BAT
DPPM
NO BATT
SHORT
AC OVP
VOVP
USB
1V
USB DETECTED
BAT
USB OVP
VOVP
VOUTSH
POWER PATH
CONTROL LOGIC
OUT SHORTED
OUT
BAT
SHORTED
VBATSH
BAT
BAT
OUT LOWER
THAN BAT
OUT
Figure 32. TPS65800 Systems Status Detection, Charger and Power Path Section
Table 4 lists the system power detection conditions. VIN(DT), VOUTSH, VBATSH, VOVP are TPS65800 internal
references, refer to the electrical characteristics for additional details.
Table 4. System Status Detection, Charger and Power Path Section
AC input voltage detected
V(AC) – V(BAT) > VIN(DT)
USB input voltage detected
V(USB) – V(BAT) > VIN(DT)
AC overvoltage detected
V(AC) > VOVP
USB overvoltage detected
V(USB) > VOVP
AC PIN TO OUT pin OR USB TO OUT PIN short detected
V(OUT) < VINOUTSH
BAT pin to OUT pin short detected
V(BAT) - V(OUT) > VBATOUTSH
Battery supplement mode need detected
V(BAT) – V(OUT) > VSUP
Blank BAT to OUT short circuit detection
V(DPPM) < 1V
Power Path Logic: Priority Algorithm
The system power bus supply is automatically selected by the power path control logic, following an internal
algorithm. The power path function detects an external input power connection when the input voltage exceeds
the battery pack voltage. It also detects a supplement mode need (battery switch must be turned ON) when the
system voltage (OUT pin) is below the battery voltage. A connected and non-selected external supply or the
battery is automatically switched to the system bus, following the priority algorithm, when the external supply
currently selected is disconnected from the system.
The input power priority is hard-wired internally, with the AC input having the higher priority, followed by the USB
input (2nd) and the battery pack (3rd). Using the I2C CHG_CONFIG register control bit CE the user can override
the power path algorithm, connecting the battery to the system power bus. Care must be taken when using the
battery to system connection option, as the system power bus is not connected back to the AC or USB inputs
(even if those are detected) when the battery is removed. Table 5 describes the priority algorithm.
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Table 5. Power Path Control Logic Priority Algorithm
CE BIT
(I2C CHG_CONFIG Register)
EXTERNAL SUPPLY
DETECTED
HI
LO
SWITCH MODE
SYSTEM POWER
SOURCE
AC
USB
AC
USB
Battery
YES
NO
ON
OFF
NO
YES
OFF
ON
ON if Supplement mode is
required, OFF otherwise
YES
YES
ON
OFF
AC
NO
NO
OFF
OFF
BATTERY
XX
XX
OFF
OFF
AC
USB
ON
BATTERY
The power path status is stored in register CHG_STAT.
Input Current Limit
The USB input current is limited to the maximum value programmed by the host, using the I2C interface. If the
system current requirements exceed the input current limit, the output voltage collapses, the charge current is
reduced, and finally the supplement mode is set. The input current limit value is set with the I2C charge control
register bits PSEL and ISET2, and it is applied to the USB input ONLY. The AC input current limit is fixed to the
internal short circuit limit value.
Table 6. Charge Current Scaling via I2C
PSEL (I2C)
ISET2 (I2C)
INPUT CURRENT LIMIT
USB
AC
LO
LO
100 mA
2.75 A
LO
HI
500 mA
2.75 A
HI
LO
2.75 A
2.75 A
HI
HI
2.75 A
2.75 A
System Voltage Regulation
The system voltage is regulated to a fixed voltage when one of the input power supplies is connected to the
system. The system voltage regulation is implemented by a control loop that modulates the selected switch
Rds(on).
The typical system regulation voltage is 4.6 V.
Input Overvoltage Detection
The AC and USB input voltages are monitored by voltage comparators that identify an overvoltage condition. If
an overvoltage condition is detected a status register bit is set, indicating a potential fault condition.
When an overvoltage condition is detected the AC or USB switches state is not modified. If any of those
switches was ON, it is kept in the ON state. During overvoltage conditions, the system voltage still is regulated,
and no major safety issues are observed when not modifying the input switch state.
If the input overvoltage condition results in excessive power dissipation, the thermal shutdown circuit is
activated, the AC and USB switches are turned OFF, and the BAT switch is turned ON.
Output Short-Circuit Detection
If the OUT pin voltage falls below an internal threshold VINOUTSH the AC and USB switches are turned off and
internal pullup resistors are connected from AC pin to OUT pin and USB pin to OUT pin. When the short circuit
is removed those resistors enable the OUT pin voltage to rise above the VINOUTSH threshold, returning the
system to normal operation.
Battery Short Circuit Detection
If the OUT pin voltage falls below the BAT pin voltage by more than an internal threshold VBATOUTSH the battery
switch is turned off and internal pullup resistor is connected between the OUT pin and the BAT pin. This resistor
enables detection of the short removal, returning the system to normal operation.
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Boot-Up Algorithm
During the initial TPS65800 power-up the contents of the ISET2, CE and SUSPEND bits on the control register
are ignored for a time period tBOOT. During that time the charger is enabled, and the selected input current limit is
set internally to 100 mA max. At the end of tBOOT period the control register settings are implemented.
No Battery Detection Circuit
The ANLG1 pin may be used to detect the connection of an external resistor that is embedded in a battery pack
and is used as a pack ID function. The ANLG1 pin has an internal current source connected between OUT and
ANLG1, which is enabled automatically when the TPS65800 is not in SLEEP mode. The current levels for
ANLG1 pin can be programmed via I2C register ADC_WAIT, bits BATID_n, as shown below:
OUT
BAT
2
IC
V(OUT) - V(NOBATID)
_
+
TPS65800
ANLG 1
PACK ID
Resistor
Battery
Figure 33. Battery Removal Detection, ANLG1 Pin
An internal comparator with a fixed deglitch time, t DGL(NOBAT) monitors the ANLG1 pin voltage, if V(ANLG1) >
V(OUT) - VNOBATID a battery removed condition is detected and an internal discharge switch is activated,
connecting an internal resistor from BAT pin to AGND1. Note that ANLG1 can also be used as an analog input
for the ADC converter, in this case the voltage at pin ANLG1 must never exceed the V(OUT) - VNOBATID
threshold to avoid undesired battery discharge.
Using the Input Power to Run the System and Charge the Battery Pack
The external supply connected to AC or USB pins must be capable of supplying the system power and the
charger current. If the external supply power is not sufficient to run the system and charge the battery pack the
TPS65800 executes a two-stage algorithm that prevents a low voltage condition at the system power bus:
1. The charge current is reduced, until the total (charger + system current) is at a level that can be supplied
by the external input supply. This function is implemented by a dedicated charger control loop (see DPPM
section in charger functional description for additional details).
2. The battery switch is turned ON if the charge current is reduced to zero and the input current is not
enough to run the system. In this mode of operation both the battery and the external input power supply
the system power ( supplement operation mode).
The supplement operation mode is automatically set by the TPS65800 when the input power is switched to the
OUT pin, and the OUT pin voltage falls below the battery voltage.
BATTERY CHARGE MANAGEMENT FUNCTION
Operating Modes
The TPS65800 supports charging of single-cell Li-Ion or Li-Pol battery packs. The charge process is executed in
three phases: precharge (or preconditioning), constant current and constant voltage.
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The charge parameters are selectable via I2C interface and using external components. The charge process
starts when an external input power is connected to the system, the charger is enabled by the I2C register
CHG_CONFIG bits CE=HI and CHGON=HI, and the battery voltage is below the recharge threshold, V(BAT) <
V(RCH). When the charge cycle starts a safety timer is activated. The safety timer timeout value is set by an
external resistor connected to TMR pin.
When the charger is enabled two control loops modulate the battery switch drain to source impedance to limit
the BAT pin current to the programmed charge current value (charge current loop) or to regulate the BAT pin
voltage to the programmed charge voltage value (charge voltage loop). If V(BAT) < 3 V (typ) the BAT pin current
is internally set to 10% of the programmed charge current value. A typical charge profile is shown below, for an
operation condition that does not cause the IC junction temperature to exceed 125°C (typ).
VO(BATREG)
Preconditioning
Phase
Current
Regulation
Phase
Voltage Regulation and
Charge Termination
Phase
DONE
IO(BAT)
Battery Current,
I(BAT)
FAST-CHARGE
CURRENT
Charge
Complete
Status,
Charger
Off
Battery voltage,
V(BAT)
V(LOWV)
IO(PRECHG) , I(TERM)
PRE-CHARGE
CURRENT AND
TERMINATION
THRESHOLD
T(PRECHG)
T(CHG)
DONE
Figure 34. Typical Charge Cycle, Thermal Loop not Active
If the operating conditions cause the IC junction temperature to exceed 125°C the charge cycle is modified, with
the activation of the integrated thermal control loop. The thermal control loop is activated when an internal
voltage reference, which is inversely proportional to the IC junction temperature, is lower than a fixed,
temperature stable internal voltage. The thermal loop overrides the other charger control loops and reduces the
charge current until the IC junction temperature returns to 125°C, effectively regulating the IC junction
temperature.
OUT
VREF
Thermal
Loop
VTJ
Battery
Switch
I(BAT)
BAT
I(OUT)/K(SET)
Charge Voltage
Loop
V(OUT)
VO(REG)
ISET 1
V(BAT)
VO(REG)
System Voltage
Regulation Loop
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A modified charge cycle, with the thermal loop active, is shown here:
VO(BATREG)
Preconditioning
Phase
Current
Thermal
Regulation Regulation
Phase
Phase
Voltage Regulation and
Charge Termination
Phase
DONE
IO(BAT)
Battery Current,
I(BAT)
FAST-CHARGE
CURRENT
Battery
Voltage,
V(BAT )
PRE-CHARGE
CURRENT AND
TERMINATION
THRESHOLD
Charge
Complete
Status,
Charger
Off
V(LOWV)
IO(PRECHG) , I(TERM)
T(THREG)
IC Junction
Temperature, Tj
T(PRECHG)
T(CHG)
DONE
Figure 35. Typical Charge Cycle, Thermal Loop Active
Battery Preconditioning
The TPS65800 applies a precharge current Io(PRECHG) to the battery if the battery voltage is below the V(LOWV)
threshold, preconditioning deeply discharged cells. The charge current loop regulates the ISET1 pin voltage to
an internal reference value, VPRECHG. The resistor connected between the ISET1 and AGND pins, RSET,
determines the precharge rate.
The precharge rate programmed by RSET is always applied to a deeply discharged battery pack, independently
of the input power selection (AC or USB). The precharge current can be calculated as follows:
V
KSET
I O(PRECHG) + PRECHG
RSET
(2)
where:
KSET is the charge current scaling factor and VPRECHG is the precharge set voltage.
CONSTANT-CURRENT CHARGING
The constant charge current mode (fast charge) is set when the battery voltage is higher than the precharge
voltage threshold. The charge current loop regulates the ISET1 pin voltage to an internal reference value, VSET.
The fast charge current regulation point is defined by the external resistor connected to the ISET1 pin, RSET, as
shown in the following:
V
KSET
I O(BAT) + SET
RSET
(3)
where:
VSET (2.5 V typ) is the voltage at ISET1 pin during charge current regulation and KSET = Charge Current
Scaling Factor.
The reference voltage VSET can be reduced via I2C register CHG_CONFIG bits ISET1_1 and ISET1_0. VSET can
be selected as a percentage (75%, 50% or 25%) of the original 2.5 V typ, non-attenuated VSET value, effectively
scaling down the charge current.
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The ISET1 resistor always sets the maximum charge current, if the AC input is selected. When the USB input is
selected, the maximum charge current is defined by the USB input current limit and the programmed charge
current. If the USB input current limit is lower than the IO(OUT) value, the battery switch is set in the dropout
region and the charge current is defined by the input current limit value and system load, as shown in the
following curves:
I(USB)
2 .75 A
INPUT
CURRENT
BATTERY
CHARGE
CURRENT
500 mA
750 mA
800 mA
(800 mA DEFINED
BY RSET VALUE)
300 mA
I(OUT )
SYSTEM LOAD
200 mA
BATTERY
CHARGING,
USB INPUT LIMIT
SET TO 2.75 A
-250 mA
BATTERY
DISCHARGING,
SUPPLEMENT
MODE SET
BATTERY
CHARGING,
INPUT LIMIT SET
TO 500 mA
Figure 36. Input Current Limit Impact on Effective Charge Current
CHARGE TERMINATION AND RECHARGE
The TPS65800 monitors the charging current during the voltage regulation phase. Charge is terminated when
the charge current is lower than an internal threshold, set to 10% (typ) of the fast charge current rate. The
termination point applies to both AC and USB charging, and it can be calculated as follows:
V
KSET
I TERM + TERM
R SET
(4)
where
VTERM is the termination detection voltage reference.
The voltage at ISET1 pin is monitored to detect termination, and termination is detected when V(SET1) < VTERM
(0.25 V typ). The voltage reference VTERM is internally set to 10% of the VSET reference voltage, and it is
modified if the reference voltage VSET is scaled via I2C register CHG_CONFIG bits ISET1_1 and ISET1_0.
VTERM is reduced by the same percentage used to scale down VSET .
The table below shows charge current and termination thresholds for a 1-A charge current set (1-kΩ resistor
connected to ISET1 pin), with the selected input current limit set to a value higher than the programmed charge
current. The termination current is scaled for all charge current modes (AC or USB), as it is always set by the
ISET1 pin external resistor value.
Table 7. Charge Current and Termination Threshold Selection Example
Charge Control Register Bits
50
Charge Current, (% of typical value
programmed by ISET1 resistor)
Vset
(V)
Vterm
(mV)
Charge
Current (A)
Termination
Current (mA)
ISET1_1
ISET1_0
0
0
25%
0.6
60
0.24
20
0
1
50%
1.25
115
0.5
40
1
0
75%
1.9
160
0.78
60
1
1
100%
2.5
250
1
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Once termination is detected, a new charge cycle starts if the voltage on the BAT pin falls below the V(RCH)
threshold. A new charge start is also triggered if the charger is enabled/disabled/enabled via I2C (CHG_CONFIG
register bits CE or CHGON), or if both AC and USB input power are removed and then at least one of them is
re-inserted.
The termination is disabled when the thermal loop OR DPPM loop are active, and during supplement mode.
BATTERY VOLTAGE REGULATION, CHARGE VOLTAGE
The voltage regulation feedback is Implemented by sensing the BAT pin voltage, which is connected to the
positive side of the battery pack. The TPS65800 monitors the battery-pack voltage between the BAT and
AGND1 pins, when the battery voltage rises to the VO(REG) threshold the voltage regulation phase begins and the
charging current tapers down.
The charging voltage can be selected as 4.2 V or 4.365 V (typ). The default power-up voltage is 4.2 V. As a
safety measure the 4.365 V charge voltage is programmed only if two distinct bits are set via I2C: VCHG = HI in
the CHG_CONFIG, and CHG_VLTG=LO in the GPIO3 register.
TEMPERATURE QUALIFICATION
The TPS65800 continuously monitors battery temperature by measuring the voltage between the TS and
AGND1 pins. An internal current source provides the bias for a negative-temperature coefficient thermistor
(NTC), and the TS pin voltage is compared to the window set by internal thresholds VLTF and VHTF to determine
if charging is allowed. A voltage outside the VLTF to VHTF window is considered a temperature fault, and charge
is suspended. Charge resumes when the temperature returns to the valid window range.
With a 50-kΩ (at 25°C) thermistor, the valid temperature window is set between 0°C to 45°C. The temperature
window can be enlarged by adding external resistors to the TS pin application circuit.
DYNAMIC POWER PATH MANAGEMENT
Under normal operating conditions, the OUT pin voltage is regulated when the AC or USB pin is powering the
OUT pin and the battery pack is being charged. If the total (system + charge current) exceeds the available input
current, the system voltage drops below the regulation value.
The dynamic power path management function monitors the system output voltage. A condition where the
external input supply rating has been exceeded or the input current limit has been reached is detected when the
OUT pin voltage drops below an user-defined threshold, VDPPM:
V DPPM + RDPPM KDPPM I DPPM
(5)
where:
RDPPM = external resistor connected to DPPM pin
KDPPM = DPPM scaling factor
IDPPM = DPPM pin internal current source
To correct this situation the DPPM loop reduces the charge current, regulating the OUT pin voltage to the
user-defined VDPPM threshold. The DPPM loop effectively identifies the maximum current that can be delivered
by the selected input and dynamically adjusts the charge current to guarantee that the end equipment is always
powered. In order to minimize OUT voltage ripple during DPPM operation the VDPPM threshold should be set just
below the system regulation voltage.
If the charge current is reduced to zero by the DPPM and the input current is still lower than the OUT pin load,
the output voltage falls below the DPPM threshold, decreasing until the battery supplement mode is set [V(OUT)
= V(BAT) – VSUP(DT) ].
CHARGER OFF MODE
The TPS65800 charger circuitry enters the low-power OFF mode if both AC and USB power are not detected.
This feature prevents draining the battery during the absence of input supply.
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PRECHARGE SAFETY TIMER
The TPS65800 activates an internal safety timer during the battery preconditioning phase. The precharge safety
timer time-out value is set by the external resistor connected to TMR pin, RTMR, and the timeout constants KPRE
and KTMR:
TPRECHG = KPRE× RTMR× KTMR
The KPRE constant typical value is 0.1, setting the precharge timer value to 10% of the charge safety timer value.
When the charger is in suspend mode, set via I2C register CHG_CONFIG bit CHGON or set by a pack
temperature fault, the precharge safety timer is put on hold (i.e., charge safety timer is not reset). Normal
operation resumes when the charger exits the suspend mode. If V(BAT) does not reach the internal voltage
threshold VPRECHG within the precharge timer period a fault condition is detected and the charger is turned off.
If the TMR pin is left floating and internal resistor, 50KΩ typ, is used to generate the timebase used to set the
precharge timeout value. The typical precharge timeout value can be then calculated as:
TPRECHG = KPRE× 50K × KTMR
CHARGE SAFETY TIMER
As a safety mechanism the TPS65800 has a user-programmable timer that measures the total fast charge time.
This timer (charge safety timer) is started at the end of the preconditioning period. The safety charge timeout
value is set by the value of an external resistor connected to the TMR pin (RTMR). The charge safety timer
time-out value is calculated as follows:
TCHG = KTMR× RTMR
When the charger is in suspend mode, set via I2C register CHG_CONFIG bit CHGON or set by a pack
temperature fault, the charge safety timer is put on hold (i.e., charge safety timer is not reset). Normal operation
resumes when the charger exits the suspend mode. If charge termination is not reached within the timer period
a fault condition is detected, and the charger is turned off.
The charge safety timer is held in reset if the TMR pin is left floating. Under this mode of operation an internal
resistor, 50KΩ typ, sets the internal charger and power path deglitch and delay times, as well as the precharge
safety timer timeout value.
TIMER FAULT RECOVERY
The TPS65800 provides a recovery method to deal with timer fault conditions. The following summarizes this
method:
• Condition 1: Charge voltage above recharge threshold, VRCH, and timeout fault occurs.
Recovery method: The IC waits for the battery voltage to fall below the recharge threshold. This could happen
as a result of a load on the battery, self-discharge or battery removal. Once the battery falls below the recharge
threshold, the IC clears the fault and starts a new charge cycle.
• Condition 2: Charge voltage below recharge threshold,V(RCH), and timeout fault occurs.
Recovery method: Under this scenario, the IC connects an internal pullup resistor from OUT pin to Bat pin.
This pullup resistor is used to detect a battery removal condition and remains on as long as the battery voltage
stays below the recharge threshold. If the battery voltage goes above the recharge threshold, the IC disables the
pullup resistor connection and executes the recovery method described for condition 1.
All timers are reset and all timer fault conditions are cleared when a new charge cycle is started either via I2C
(toggling CHG_CONFIG bits CE, CHGON) or by cycling the input power. All timers are reset and all timer fault
conditions are cleared when the TPS65800 enters the UVLO mode.
DYNAMIC TIMER FUNCTION
The charge and precharge safety timers are programmed by the user to detect a fault condition if the charge
cycle duration exceeds the total time expected under normal conditions. The expected total charge time is
usually calculated based on the fast charge current rate.
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When the thermal loop or the DPPM loops are activated the charge current is reduced, and a false safety timer
fault can be observed if this mode of operation is active for a long periods. To avoid this undesirable fault
condition the TPS65800 activates the dynamic timer function when the DPPM and thermal loops are active. The
dynamic timer function slows down the safety timers clock, effectively adding an extra time to the programmed
timeout value as follows:
1. If the battery voltage is below the battery depleted threshold: the precharge timer value is modified while
the thermal loop or the DPPM loop are active
2. If the battery voltage is above the precharge threshold: the safety timer value is modified if the DPPM or
the thermal loop are active AND the battery voltage is below the recharge threshold.
The TPS65800 dynamic timer function circuit monitors the voltage at pin ISET1 during precharge and fast
charge. When the charger is regulating the charge current, the voltage at pin ISET1 is regulated by the control
loops to either VSET or VPRECHG. If the thermal loop or DPPM loops are active, the voltage at pin ISET1 is lower
than VSET or VPRECHG, and the dynamic timer control circuit changes the safety timers clock period based on the
VSET/V(ISET1) ratio (fast charge) or VPRECHG/V(ISET1) ratio (precharge).
TIMER INTERNAL CLOCK PERIOD
MULTIPLICATION FACTOR
The maximum clock period is internally limited to twice the value of the programmed clock period, which is
defined by the resistor connected to TMR pin, as shown in the following figure:
2
1
1
2
V(SET)
V(SET 1)
,
V(PRECHG)
V(ISET 1)
Figure 37. Safety Timer Internal Clock Slowdown
The effective charge safety timer value can then be expressed as follows:
Effective precharge timeout = t(PRECHG) + t(PCHGADD)
Effective charge safety timeout = t(CHG) + t(CHGADD)
Where the added timeout values, t(PCHGADD), t(CHGADD), are equal to the sum of all time periods when either the
thermal loop or DPPM loops were active. The maximum added timeout value is internally limited to 2 × t(CHG) or
2 × t(PRECHG)
CHARGE AND SYSTEM POWER MANAGEMENT — I2C REGISTERS
The I2C registers that control charger and power path related functions are shown below. The HEX address for
each register is shown by the register name, together with the R or W functionality for the register bits. Shaded
values indicate default initial power-up values. Note that the CHG_STAT register contents are valid only when
either AC or USB power are applied to the TPS65800. The output of linear regulator LDO_PM can be used as
an indicator of external input power detection; if LDO_PM is in regulation the CHG_STAT register contents are
valid.
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CHG_CONFIG, ADDRESS=9, ALL BITS R/W
B7
B6
B5
B4
B3
B2
B1
B0
Bit name
VCHG
CHGON
NOT USED
ISET1_1
ISET1_0
ISET2
PSEL
CE (1)
Function
CHARGE
VOLTAGE
SELECTION
SUSPEND
CHARGE
NOT USED
USB
CURRENT
LIMIT
SELECTED
INPUT
CURRENT
LIMIT
SYSTEM
POWER
SELECTION
When 0
4.36 V
CHARGE
SUSPENDED
NOT USED
100 mA
USE USB
CURRENT
LIMIT
BATTERY TO
SYSTEM
When 1
4.2 V
CHARGE ON
NOT USED
500 mA
INPUT
CURRENT
LIMIT SET TO
MAXIMUM
INPUT POWER
TO SYSTEM (1)
(1)
CHARGE CURRENT SCALING
FACTOR
00= 0.25 10=0.75
01= 0.5 11= 1
Note: Relative to Charge Current
Programmed by external ISET pin
resistor.
The CE bit state is latched inside the charger control logic (CE latch) during an OUT pin UVLO event, prior to resetting the charge
control register bit CE to its power up default value. The charger CE latch controls the charger and power path state as long as the
TPS65800 is in UVLO mode and an external supply is connected to the charger block. The CE latch is reset to its power-up value
(CE=HI) only when the input power is removed from the charger block. The CE latch is disabled and the CE charge control register bit
sets the charger and power path MOSFETs state when the TPS65800 exits the UVLO mode. This feature avoids a host software loop
when the host algorithm requires a depleted (or absent) battery to be connected to the system bus while input power is present.
GPIO3, ADDRESS = 1C, ALL BITS R/W. NOTE: ONLY BIT B4 CONTROLS CHARGER-RELATED FUNCTIONALITY.
B7
B6
B5
B4
B3
B2
B1
B0
Bit name
GPIO3i/O
GPIO3_LEVEL
LDO0_ENABLE
CHARGE _VLTG
NOT USED
GPIO2 _INTSRC
GPIO1 _INTSRC
GPIO2 _SM2
Function
SEE
Table 15
SEE Table 15
SEE Table 15
CHARGE
VOLTAGE
SELECTION
SAFETY BIT
NOT USED
SEE Table 15
SEE Table 15
SEE Table 15
When 0
4.2 V
When 1
4.36 V
CHG_STAT, ADDRESS = A, ALL BITS READ ONLY. POWER-UP DEFAULTS SHOW SYSTEM STATUS WHEN EXITING POWER DOWN.
B7
B6
B5
B4
B3
B2
B1
B0
Bit name
BAT_STAT (1) (2)
INPUT _PWR
THDPPM_ON
ACPG (3)
USBPG (3)
STAT1
STAT2
INP_OV
Function
BATTERY
SUPPLEMENT
MODE STATUS
SELECTED
INPUT
POWER
STATUS
THERMAL
LOOP AND
DPPM
STATUS
AC INPUT
POWER
STATUS
USB INPUT
POWER
STATUS
When 0
SUPPLEMENT
MODE OFF
AC INPUT
SELECTED
BOTH OFF
AC NOT
DETECTED
USB NOT
DETECTED
When 1
SUPPLEMENT
MODE ON
USB INPUT
SELECTED
DPPM ON OR
THERMAL ON
AC
DETECTED
USB
DETECTED
(1)
(2)
(3)
54
CHARGE STATUS
00
01
10
11
= FAULT/OFF/SUSPEND
= CHARGE DONE
= FAST CHARGE ON
= PRECHARGE ON
AC OR USB
INPUT OVP
DETECTION
NO OVP
OVP
DETECTED
The battery supplement is entered when V(BAT)– V(OUT) > 60 mV (typ), and it ends when V(BAT)– V(OUT) < 20 mV. When the system
power bus current exceeds the input current limit or the external supply current capability, the supplement mode is set. An oscillatory
behavior for BAT_STAT bit can happen if the battery switch dropout voltage is less than 20 mV (typ) when in supplement mode.
The BAT_STAT is always masked internally, and does not generate interrupts.
The ACPG and USBPG bits have valid data only when V(LDO_PM) > 2.0 V.
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FUNCTIONALITY GUIDE — LINEAR REGULATORS
SELECTABLE OUTPUT VOLTAGE LDO
Supply
ON/OFF
Control
Output Discharge
Switch
LDO1
Yes, set via
I2C
LDO2
SIM
OUTPUT VOLTAGE (V), set via I2C
IO Max
(mA)
Acc
%
Power Up
Default
1.25/1.5/1.8/2.5/2.85/3/3.2/3.3
150
3
ON, 2.85 V
8
1.25/1.5/1.8/2.5/2.85/3/3.2/3.3
150
3
ON, 3.3 V
2
1.8 / 3
8
2
OFF, 1.8 V
IO Max
(mA)
Acc
%
Power Up
Default
# of Steps
Available Values (V)
Yes, enabled via I2C
8
Yes, set via
I2C
Yes, enabled via I2C
Yes, set via
I2C
No
PROGRAMMABLE OUTPUT VOLTAGE LDO
OUTPUT VOLTAGE (V), set via I2C
Supply
ON/OFF
Control
Output Discharge
Switch
Range
# of Steps
Min Step
LDO3
Yes, set via
I2C
Yes, enabled via I2C
1.224–4.46
128
25 mV
100
3
ON, 1.25 V
LDO4
Yes, set via
I2C
Yes, enabled via I2C
1.224–4.46
128
25 mV
100
3
ON, 2.75 V
yes, set via I2C Yes, enabled via I2C
1.224–4.46
128
25 mV
100
3
ON, 2.81 V
IO Max (mA)
Acc %
LDO5
FIXED OUTPUT VOLTAGE LDO’S
Supply
ON/OFF Control
OUTPUT
VOLTAGE (V)
RTC_OUT
Yes, via I2C
3.1, fixed
8
5
ON
3.3, fixed
150
3
OFF
3.3, fixed
20
5
ON if AC or USB power detected
LDC0
LDO_PM
NO, enabled internally
Power Up Default
1.25-3.3 V
150 mA
3.1 V
8 mA
3.3 V
10 mA
1.25-3.3 V
150 mA
3.3 V
150 mA
A2
OUT
SIM
100 mF
C4
C3
1 mF
L DO_P M
RTC_O UT
1.8 V / 3 V
8 mA
C5
LDO0
4.7 mF
C8
L DO 2
4.7 mF
C10
LDO1
4.7 mF
C9
VIN_L DO12
4.7 mF
C6
AG ND2
2.2 mF
C13
LDO3
2.2 mF
C14
LDO4
2.2 mF
C15
L DO5
0.1 mF L DO 35 _REF
1.224-4.4 V
100 mA
2.2 mF
1.224-4.4 V
100 mA
ON /OFF
Output Voltage
ON /OFF
AG ND1
HIG H PSRR L DO S
1.224-4.4 V
100 mA
C12
VIN_ LDO3 5
1 mF
C11
ON /OFF , Output Voltage
Discharge Control
C7 1 mF
I2 C
REG ISTERS
TPS65800
A1
Figure 38. Required External Components, Recommended Values, External Connections
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LINEAR REGULATORS — FUNCTIONAL DESCRIPTION
The TPS65800 offers nine integrated linear regulators, designed to be stable over the operating load range with
use of external ceramic capacitors, as long as the recommended filter capacitor values (see application diagram
and pinout description) are used. The output voltage can be programmed via I2C (LDO0-2, LDO3-5) or have a
fixed output voltage.
Simplified Block Diagram
A simplified block diagram for the LDOs is shown in Figure 39.
INPUT SUPPLY
VREF
_
I2C
REGISTERS
OUTPUT
VOLTAGE
SAMPLE
ON/OFF
CONTROL
OUTPUT VOLTAGE
+
All LDOs
except
LDO_PM
BIAS
CONTROL
LDO3-5 ONLY
SHORT CIRCUIT
PROTECTION
OUTPUT
VOLTAGE
SETTING
OUTPUT
CURRENT
SAMPLE
Programmable
LDOs only
DISCHARGE
CONTROL
ENABLE
LDO1, LDO2,
LDO3-5 ONLY
DISCHARGE
CONTROL
LDO1, LDO2,
LDO3-5 ONLY
Figure 39. Simplified Block Diagram
Connecting the LDO Input Supply
Both LDO1-2 and LDO3-5 have uncommitted input power supply pins (VIN_LDO12, VIN_LDO35), which should
be externally connected to the OUT pin. Optionally the LDO0-2 and LDO3-5 input supplies can be connected to
the output of the available buck converters SM1 or SM2, as long as the resulting overall power-up sequence
meets the system requirements.
The RTC_OUT, SIM, LDO0 and LDO_PM linear regulators are internally connected to the OUT pin.
ON/OFF Control
All the LDO’s, with exception of LDO_PM LDO, have a ON/OFF control which can be set via I2C commands,
facilitating host management of the distinct system power rails. The LDO_PM LDO On/OFF control is internally
hard-wired, and it is set to ON when either the AC or USB input power is detected.
Output Discharge Switch
LDO1, LDO2 AND LDO3-5 have integrated switches that discharge each output to ground when the LDO is set
to OFF by an I2C command. The output discharge switch function can be disabled by using I2C register control
bits. The discharge switches are enabled after the initial power-up
Special Functions
The RTC_OUT, SIM (Subscriber line interface module) and LDO_PM linear regulators are designed to support
lower load currents. The SIM and RTC_LDO have low leakage in OFF mode, with the input pin voltage above or
below the output pin voltage. The LDO_PM can be used for USB enumeration, or a status indication of input
power connection.
56
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Output Voltage Monitoring
Internal power good comparators monitor the LDO outputs and detect when the output voltage is below 90% of
the programmed value. This information is used by the TPS65800 to generate interrupts or to trigger distinct
operating modes, depending on specific I2C register settings. See interrupt and sequencing controller section for
additional details.
LINEAR REGULATORS — I2C REGISTERS
The I2C registers that control LDO-related functions are shown below. The HEX address for each register is
shown by the register name, together with the R or W functionality for the register bits. Shaded values indicate
default initial power-up values.
B7
B6
B5
B4
B3
LDO2_EN
LDO3_EN
LDO4_EN
LDO5_EN
B2
B1
B0
SIM EN1
RTC_EN
EN_LDO: ADRESS = B, ALL BITS R/W
Bit name
LDO1_EN
Function
LDO1…5 ON/OFF CONTROL
SIM_SET
SIM LDO output
voltage
SIM/RTC ON/OFF CONTROL
When 0
OFF
OFF
OFF
OFF
OFF
3.0 V
OFF
OFF
When 1
ON
ON
ON
ON
ON
1.80 V
ON
ON
LDO1_2 SET
LDO1_1 SET
LDO1_0 SET
LDO2_DISCH
LDO2_2 SET
LDO2_1 SET
LDO2_0 SET
LDO12: ADRESS = C, ALL BITS R/W
Bit name
LDO1_DISCH
Function
LDO1 output
discharge switch
enable
When 0
OFF
When 1
ON
LDO1 OUTPUT VOLTAGE SETTING
000
010
100
110
=
=
=
=
1.25 V
1.8 V
2.85 V
3.2 V
001 = 1.5 V
011 = 2.5 V
110 = 3 V
111 = 3.3
Default = 2.85 V
LDO2 Output
discharge
switch enable
OFF
ON
LDO2 OUTPUT VOLTAGE SETTING
000 =
010 =
100 =
110 =
1.25 V
1.8 V
2.85 V
3.2 V
001 = 1.5 V
011 = 2.5 V
110 = 3 V
111 = 3.3 V
Default = 3.3 V
LDO3, ADDRESS = D, ALL BITS R/W
Bit name
LDO3_DISCH
Function
LDO3 output
discharge switch
enable
LDO3_6 SET
LDO3_5 SET
LDO3_4 SET
LDO3 OUTPUT VOLTAGE SETTING
LDO3_3 SET
LDO3_2 SET
LDO3_1 SET
When 0
OFF
SeeTable 8 for LDO3-5 output voltage setting, power-up default = 1.25 V
When 1
ON
LDO3_0 SET
LDO4, ADRESS = E, ALL BITS R/W
Bit name
LDO4_DISCH
Function
LDO4 output
discharge switch
enable
LDO4_6 SET
LDO4_5 SET
LDO4_4 SET
LDO4 OUTPUT VOLTAGE SETTING
LDO4_3 SET
LDO4_2 SET
LDO4_1 SET
When 0
OFF
See Table 8 for LDO3-5 output voltage setting, power-up default = 2.75 V
When 1
ON
LDO4_0 SET
LDO5, ADRESS = F, ALL BITS R/W
Bit name
LDO5_DISCH
Function
LDO5 output
discharge switch
enable
LDO5_6 SET
LDO5_5 SET
LDO5_4 SET
LDO5 OUTPUT VOLTAGE SETTING
LDO5_3 SET
LDO5_2 SET
LDO5_1 SET
When 0
OFF
See Table 8 for LDO3-5 output voltage setting, power-up default = 2.81 V
When 1
ON
LDO5_0 SET
GPIO3, ADDRESS = 1C, ALL BITS R/W. NOTE: ONLY BIT B5 CONTROLS LDO-RELATED FUNCTIONALITY
Bit name
GPIO3i/O
GPIO3 LEVEL
LDO0 ENABLE
CHARGE
_VLTG
NOT USED
Function
SEE Table 15
SEE Table 15
LDO0 ON/OFF
CONTROL
SEE
CHARGER
SECTION
Battery Voltage
Regulation,
Charge Voltage
NOT USED
When 0
LDO0 OFF
When 1
LDO0 ON
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GPIO2 _INTSRC GPIO1 _INTSRC
SEE Table 15
SEE Table 15
GPIO2 _SM2
SEE Table 15
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Table 8. LDO 3–5 Programming Step Values
58
Step
B6–B0
Vset
Step
B6–B0
Vset
Step
B6–B0
Vset
Step
B6-B0
Vset
0
000 0000
1.224
32
010 0000
2.040
64
100 0000
2.015
96
110 0000
2.856
1
000 0001
1.250
33
010 0001
2.066
65
100 0001
2.040
97
110 0001
2.882
2
000 0010
1.275
34
010 0010
2.091
66
100 0010
2.907
98
110 0010
3.723
3
000 0011
1.301
35
010 0011
2.117
67
100 0011
2.933
99
110 0011
3.749
4
000 0100
1.326
36
010 0100
2.142
68
100 0100
2.958
100
110 0100
3.774
5
000 0101
1.352
37
010 0101
2.168
69
100 0101
2.984
101
110 0101
3.800
6
000 0110
1.377
38
010 0110
2.193
70
100 0110
3.009
102
110 0110
3.825
7
000 0111
1.403
39
010 0111
2.219
71
100 0111
3.035
103
110 0111
3.851
8
000 1000
1.428
40
010 1000
2.244
72
100 1000
3.060
104
110 1000
3.876
9
000 1001
1.454
41
010 1001
2.270
73
100 1001
3.086
105
110 1001
3.902
10
000 1010
1.479
42
010 1010
2.295
74
100 1010
3.111
106
110 1010
3.927
11
000 1011
1.505
43
010 1011
2.321
75
100 1011
3.137
107
110 1011
3.953
12
000 1100
1.530
44
010 1100
2.346
76
100 1100
3.162
108
110 1100
3.978
13
000 1101
1.556
45
010 1101
2.372
77
100 1101
3.188
109
110 1101
4.004
14
000 1110
1.581
46
010 1110
2.397
78
100 1110
3.213
110
110 1110
4.029
15
000 1111
1.607
47
010 1111
2.423
79
100 1111
3.239
111
110 1111
4.055
16
001 0000
1.632
48
011 0000
2.448
80
101 0000
3.264
112
111 0000
4.080
17
001 0001
1.658
49
011 0001
2.474
81
101 0001
3.290
113
111 0001
4.106
18
001 0010
1.683
50
011 0010
2.499
82
101 0010
3.315
114
111 0010
4.131
19
001 0011
1.709
51
011 0011
2.525
83
101 0011
3.341
115
111 0011
4.157
20
001 0100
1.734
52
011 0100
2.550
84
101 0100
3.366
116
111 0100
4.182
21
001 0101
1.760
53
011 0101
2.576
85
101 0101
3.392
117
111 0101
4.208
22
001 0110
1.785
54
011 0110
2.601
86
101 0110
3.417
118
111 0110
4.233
23
001 0111
1.811
55
011 0111
2.627
87
101 0111
3.443
119
111 0111
4.259
24
001 1000
1.836
56
011 1000
2.652
88
101 1000
3.468
120
111 1000
4.284
25
001 1001
1.862
57
011 1001
2.678
89
101 1001
3.494
121
111 1001
4.310
26
001 1010
1.887
58
011 1010
2.703
90
101 1010
3.519
122
111 1010
4.335
27
001 1011
1.913
59
011 1011
2.729
91
101 1011
3.545
123
111 1011
4.361
28
001 1100
1.938
60
011 1100
2.754
92
101 1100
3.570
124
111 1100
4.386
29
001 1101
1.964
61
011 1101
2.780
93
101 1101
3.596
125
111 1101
4.412
30
001 1110
1.989
62
011 1110
2.805
94
101 1110
3.621
126
111 1110
4.437
31
001 1111
2.015
63
011 1111
2.831
95
101 1111
3.647
127
111 1111
4.463
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FUNCTIONALITY GUIDE — SWITCHED MODE STEP-DOWN CONVERTERS
BUCK CONVERTERS, I2C PROGRAMMABLE OUTPUT VOLTAGE
Supply
PFM Mode
SM1
PFM/PWM
with
automatic
mode
selection or
PWM only.
SM2
Mode of
operation set
via I2C
Standby
Mode
Standby
mode
with
distinct
voltage
available
.
Standby
mode set
via I2C
or with
GPIO pin
OUTPUT VOLTAGE (V), Set via I2C,
Separate Settings for Normal or
Standby Mode
IO Max
(mA)
Range
# of Steps
Min
Step
Acc
(%)
0.6-1.8
32
40 mV
3
600
1.0-3.4
32
80mV
3
600
TPS65800
PWM Freq
and Phase
SLEW RATE, mV/µS, Set
via I2C
Power Up Default
Range
# of
Steps
Min
Step
1.5MHz, 0°
0, 0.24
to 15.36
8
0.24
ON, skip mode off,
PWM only, 1.24
V(on/sby),
15.36mV/µS
1.5MHz,
0/90/180
270°, with
respect to
SM1, set via
I2C
0,
0.4830.72
8
0.48
ON, skip mode on,
PWM/PFM, 1.8 V
(on/sby), 180°,
30.72mV/µS
OUT
VO(SM1)
I2C REGISTERS
Operating Mode
Output Voltage
Phase Control
Discharge Control
SYNC BUCK
0.6-1.8 V
600 mA
VIN_ SM1
L1
SM1
LSM 1
3.3 mH
C21
10 mF
C22
10 mF
PGND 1
VO(SM2)
P1
VIN_ SM2
Operating Mode
Output Voltage
Phase Control
Discharge Control
1.0-3.4 V
600 mA
L2
SM2
LSM 2
3.3 mH
C19
10 mF
C20
10 mF
PGND 2
P2
Figure 40. Required External Components, Recommended Values, External Connections
STEP-DOWN SWITCHED MODE CONVERTERS: SM1 and SM2
The TPS65800 has two highly efficient step down synchronous converters. The integration of the power stage
switching MOSFETs reduces the external component count, and only the external output inductor and filter
capacitor are required. The integrated power stage supports 100% duty cycle operation. Multiple operation
modes are available, enabling optimization of the overall system performance under distinct load conditions.
The converters have two modes of operation: a 1.5 MHz fixed frequency pulse width modulation (PWM) mode at
moderate to heavy loads, and a pulse frequency modulation (PFM) mode at light loads. The converter output
voltage is programmable via I2C registers SM1_SET1 and SM2_SET1.
When the SM1/SM2 converters are disabled an integrated switch automatically discharges the converter output
capacitor. The discharge switch function can be disabled by setting the control bits DISCHSM1 and DISCHSM2
to LO, in I2C registers SM1_SET2 and SM2_SET2.
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TPS65800
SM1 OUTPUT
VOLTAGE SETTING
SM 1 CONVERTER
EN_PFM
DAC
OUT
VIN_SM1
PWM CONTROL
PWMON
EN_PWM
GATE
CONTROL
LOGIC
I2C
REGISTERS
PFM CONTROL
POWER STAGE
CURRENT COMPARATORS
SM1 OPERATING
MODE :
ON/OFF,
PWM, PFM, STANDBY
SM1 DISCHARGE
SWITCH ENABLE ,
LOW PFM RIPPLE
I(L1)
+
_
LSM 1
C21
C22
10 µF
10 µF
PGND 1
V ( V I N _ S M 1)
29 Ω
+
V(VIN_SM1)
_
39 Ω
EN_PFM
EN_PWM
EN_ALL
P1
SM1
CONTROL DCHGON
LOGIC
SM1
SM2 OUTPUT
VOLTAGE SETTING
SM2 OPERATING
MODE :
ON/OFF ,
PWM,PFM,
PFM,STANDBY
STANDBY
PWM,
SM1 DISCHARGE
SWITCH ENABLE ,
LOW PFM RIPPLE
VO(SM1)
3.3 µH
I(L1)
PFMON
RESET
OUT
SET
L1
VIN_SM2
L2
SM2 CONVERTER
SAME TOPOLOGY AS SM1 CONVERTER
VO(SM2)
3.3 µH
LSM2
C19
10 µF
PGND2
C20
10 µF
SM2
SM1/SM2 PHASE
CONTROL
P2
Figure 41. SM1/SM2 Converter
The TPS65800 SM1 and SM2 buck converters can be set to operate only in PWM mode or to switch
automatically between PFM and PWM modes. The average load current is monitored, and the PFM mode is set
if the average load current is below the threshold IPFM(ENTER). When in PFM mode the load current is also
monitored, and the PWM mode is set when the load current exceeds the threshold IPFM(LEAVE). The thresholds
for automatic PFM/PWM switching are calculated as shown in Equation 6 for the SM1 converter, the same
thresholds apply to the SM2 converter by replacing VIN_SM1 by VIN_SM2:
V(VIN_SM3)
V(VIN_SM3)
I PFM(ENTER) +
I PFM(LEAVE) +
,
39 W
29 W
(6)
The automatic switching mode is enabled via the control bits PFM_SM1 and PFM_SM2 on I2C registers
SM1_SET1 and SM2_SET1.
Output Voltage Slew Rate
I2C registers enable setting the output voltage slew rate, when transitioning from one programmed voltage to a
new programmed voltage value. These events can be triggered by a new output voltage selection or by
switching from a low power mode (standby) to a normal operating mode. During a transition, the output voltage
is stepped from the currently programmed voltage to the new target voltage. The slew rate from the initial
voltage to the final voltage can be selected using I2C registers, SM1_SET2 and SM2_SET2, ranging from 0.24
mv/µs to 15.36 mV/µs for the SM1 converter and 0.48 to 30.72 mV/µS for the SM2 converter. If the slew rate is
set to OFF, the output voltage goes from the current value to the programmed value in a single step.
During the transition to standby mode the Power Good comparators are disabled.
60
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Soft Start
SM1 and SM2 have an internal soft start circuit that limits the inrush current during start-up. An initial delay (170
µs typ) from the converter enabled command to the converter effectively being operational is required, to assure
that the internal circuits of the converter are properly biased. At the end of that initial delay the soft start is
initiated, and the internal compensation capacitor is charged with a low value current source. The soft start time
is typically 750 µs, with the output voltage ramping from 5% to 95% of the final target value.
Dropout Operation at 100% Duty Cycle
The TPS65800 buck converters offer a low input to output voltage difference while still maintaining operation
when the duty cycle is set to 100%. In this mode of operation the P-channel switch is constantly turned on,
enabling operation with a low input voltage. Dropout operation starts if:
ǒ
Ǔ
V(VIN_SM1) v V(SM1) ) I(L1) RDSON(PSM1) ) RL
(7)
Where:
I(L1) = Output current plus inductor ripple current.
RL = DC resistance of the inductor
Equation 7 can be also used for the SM2 converter, replacing SM1 by SM2 and L1 by L2.
Output Voltage Monitoring
The output voltage of converters SM1 and SM2 is monitored by internal comparators, and an output low voltage
condition is detected when the output voltage is below 90% of the programmed value. The power good status
for SM1 and SM2 is accessible via I2C, see interrupt controller section for more details.
The power good comparators for SM1 and SM2 are disabled during the transition to standby mode operation.
They are enabled when the transition to standby mode is complete.
Standby Mode
Using the I2C SM1 and SM2 can be set in stand-by mode. In STANDBY mode the PFM operation mode is set
and the output voltage is defined by I2C registers SM1_STANDBYand SM2_STANDBY, and it can be set to a
value different than the normal mode output regulation voltage. The standby mode can also be set by the GPIO
pins, if those are configured as control pins that define the SM1/SM2 operating mode.
PWM Operation
During PWM operation the converters use a fast response voltage mode controller scheme with input voltage
feed-forward, enabling the use of small ceramic input and output capacitors. At the beginning of each clock cycle
the P-channel MOSFET switch is turned on, and the oscillator starts the voltage ramp. The inductor current
ramps up until the ramp voltage reaches the error amplifier output voltage, when the comparator trips and the
p-channel MOSFET switch is turned off. Internal adaptative break-before-make circuits turn on the integrated
n-channel MOSFET switch after an internal, fixed dead-time delay, and the inductor current ramps down, until
the next cycle is started. When the next cycle starts the ramp voltage is reset to its low value and the p-channel
MOSFET switch is turned on again.
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PWM CONTROL SECTION
(SHOWN FOR SM1, SAME TOPOLOGY FOR SM2)
ERROR AMP WITH “TYPE-3
LIKE” COMPENSATION
OUT
_
OUTPUT
VOLTAGE
SETTING
VIN_SM1
+
+
OSC
_
GATE
CONTROL
LOGIC
RAMP PEAK-TO-PEAK VOLTAGE
PROPORTIONAL TO VIN_SM1
L1
(L1)
PGND1
VO(SM1)
3.3 mH
LSM1
C21
10 mF
C22
10 mF
SM1
Figure 42. PWM Operation
The integrated power MOSFETs current is monitored at all times and the power MOSFET is turned off if its
internal short circuit current limit is reached.
Phase Control in PWM Mode
The SM1 and SM2 converters operate synchronized to each other when both are in PWM mode, with converter
SM1 as the master. I2C control register bits S1S2PHASE in register SM1_SET2 enables delaying the SM2 PWM
clock with respect to SM1 PWM clock, selecting a phase shift from 0 to 270 degrees. The out-of-phase operation
reduces the average current at the input node, enabling use of smaller input filter capacitors when both
converters are connected to the same input supply.
PFM Mode Operation
Using the I2C interface the SM1 and SM2 converters can have the automatic power saving PFM mode enabled.
When the PFM mode is set the switching frequency is reduced and the internal bias currents are decreased,
optimizing the converter efficiency under light load conditions.
In PFM mode the output voltage is monitored by a voltage comparator, which regulates the output voltage to the
programmed value VO(SM1). If the output voltage is below VO(SM1) the PFM control circuit turns on the power
stage, applying a burst of pulses to increase the output voltage. When the output voltage exceeds the target
regulation voltage VO(SM1), the power stage is disabled, and the output voltage drops until it is below the
regulation voltage target, when the power stage is enabled again.
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OUT
VIN_SM1
PFM CONTROL SECTION
(SHOWN FOR SM1, SAME TOPOLOGY FOR SM2)
GATE
CONTROL
LOGIC
POWER STAGE PEAK
CURRENT COMPARATORS
_
-
LSM1
+
RESET
+
C21
10 mF
C22
10 mF
PGND1
I(L 1)
_
VO(SM1)
3.3 mH
I(L1)
OUTPUT VOLTAGE
COMPARATOR
VO(SM1)
L1
V(VIN_SM1)
29 W
P1
OUT
SET
BIAS CONTROL
+
_
V(VIN_SM1)
39 W
SM1
Figure 43. PFM Mode Operation
During burst operation two current comparators control the power stage integrated MOSFETs. These
comparators monitor the instantaneous inductor current and compare it to the internal thresholds IPFM(ENTER) and
IPFM(LEAVE), turning the p-channel switch on if the inductor current is less than IPFM(LEAVE) and turning it off if the
inductor current exceeds IPFM(ENTER). The n-channel switch is turned on when the p-channel MOSFET is off.
The PFM output voltage comparator quiescent current may be reduced using the I2C register bits PFM_RPL1
and PFM_RPL2 in registers SM1_SET and SM2_SET. The voltage comparator quiescent current is reduced if
PFM_RPL1 and PFM_RPL2 bits are set to LO, and the comparator response time (tCOMP, see Figure 44)
increases. A reduction in quiescent current increases the converter efficiency at light loads, at the expense of a
larger output voltage ripple when in PFM mode.
The ripple is minimized if PFM_RPL1 and PFM_RPL2 bits are set to HI, at the expense of reduced efficiency
under light loads. The operation under low and high ripple settings is described in Figure 44.
TCOMP
TCOMP
TCOMP
TCOMP
V(OUT)
OUTPUT
VOLTAGE
IPFM(ENTER)
IPFM(LEAVE)
BURST
LOW RIPPLE
PFM OPERATION
INDUCTOR
CURRENT
BURST
MAXIMUM EFFICIENCY
PFM OPERATION
Figure 44. PFM mode operation waveforms
When a burst of pulses is generated, the PFM current comparators control the power stage MOSFETs to limit
the inductor current to a value between the thresholds IPFM(LEAVE) and IPFM(ENTER). The number of pulses in a
burst cycle is proportional to the load current, and the average current is always below IPFM(LEAVE) once PFM
operation is set. The typical burst operation in PFM mode is shown in Figure 45.
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BURST
V(OUT)
IPFM(ENTER)
INDUCTOR CURRENT
IPFM(LEAVE)
IPFM(LEAVE)
LOAD CURRENT
Figure 45. Typical Burst Operation in PFM Mode
The PFM operation is disabled and PWM operation set if one of the following events happen during PFM
operation:
1. The total burst operation time exceeds 10 µs, typ.
2. The output voltage falls below 2% of the target regulation voltage.
The PFM mode can be disabled through the serial interface to force the individual converters to stay in fixed
frequency PWM mode.
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SWITCHED MODE STEP-DOWN CONVERTERS — I2C REGISTERS
The I2C registers that control buck converter-related functions are shown below. The HEX address for each
register is shown by the register name, together with the R or W functionality for the register bits. Shaded values
indicate default initial power-up values.
B7
B6
B5
B4
B3
B2
B1
B0
SetV4_SM1
SetV3_SM1
SetV2_SM1
SetV1_SM1
SetV0_SM1
SM1_SET1, ADDRESS=10, ALL BITS R/W
Bit name
SM1 EN
PFM_RPL1
PFM_SM1
Function
SM1 ON/OFF
CONTROL
SM1 PFM
FUNCTION
OPERATION
SM1 PFM
MODE ON/OFF
CTRL
When 0
OFF
MAXIMIZE
EFFICIENCY
PWM/PFM
When 1
ON
MINIMIZE
OUTPUT
RIPPLE
Only PWM
SM1 OUTPUT VOLTAGE REGULATION VALUE, STANDBY MODE NOT SET
See Table 9 for SM1, SM2 voltage setting,
Power up default=1.24 V
SM1_SET2, ADDRESS=11, ALL BITS R/W
Bit name
NOT USED
STANDBY_SM
1
DISCHSM1
Function
NOT USED
SM1 STANDBY
MODE ON
SM1 output
discharge
switch enable
When 0
NOT USED
OFF
OFF
When 1
NOT USED
ON
ON
S1S2PHASE_1
S1S2PHASE_0
SM2 PWM CLOCK DELAY,
WITH RESPECT TO SM1 PWM
CLOCK
SLEWSM1_2
SLEWSM1_1
SLEWSM1_0
SM1 OUTPUT SLEW RATE SETTING
00 = 0 10 = 180
01 = 90 11 = 270
Units: degrees
Default= 180
000 = 0.24 010 = 0.96 100 = 5.84 110 = 15.36
001 = 0.48 011 = 1.92 101 = 7.68 111 =
IMMEDIATE
Unit: mV/µs
Default= 15.36
SetV4_SM1SL
SetV2_SM1SL
SM1_STANDBY, ADDRESS=12, B4-B0 R/W, B7-B5 READ ONLY
Bit name
NOT USED
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
SM1 OUTPUT VOLTAGE REGULATION VALUE, STANDBY MODE SET
SetV3_SM1SL
SetV1_SM1SL
SetV0_SM1SL
When 0
NOT USED
NOT USED
NOT USED
See Table 9 for SM1, SM2 voltage setting, Power up default=1.24 V
When 1
NOT USED
NOT USED
NOT USED
SM2_SET1, ADDRESS=13, ALL REGISTER BITS R/W
Bit name
SM2 EN
PFM_RPL2
PFM_SM2
Function
SM2 ON/OFF
CONTROL
SM2 PFM
FUNCTION
OPERATION
SM2 PFM
MODE ON/OFF
CTRL
SetV4_SM2
SM2 OUTPUT VOLTAGE REGULATION VALUE, STANDBY MODE NOT SET
SetV3_SM2
SetV2_SM2
SetV1_SM2
SetV0_SM2
When 0
OFF
MAXIMIZE
EFFICIENCY
PWM/PFM
See Table 9 for SM1, SM2 voltage setting,Power up default=1.80 V
When 1
ON
MINIMIZE
OUTPUT
RIPPLE
ONLY PWM
SM2_SET2, ADDRESS=14, ALL REGISTER BITS R/W
Bit name
NOT USED
STANDBY_SM
2
DISCHSM2
NOT USED
NOT USED
Function
NOT USED
SM2 STANDBY
MODE ON
SM2 output
discharge
switch enable
NOT USED
NOT USED
When 0
NOT USED
OFF
OFF
NOT USED
NOT USED
When 1
NOT USED
ON
ON
NOT USED
NOT USED
SetV4_SM2SL
SetV3_SM2SL
SLEWSM2_2
SLEWSM2_1
SLEWSM2_0
SM2 OUTPUT SLEW RATE SETTING
000 = 0.48 010 = 1.92 100 = 7.68
110 = 30.72 001 = 0.096 011 = 3.84
101 = 15.36 111 = IMMEDIATE
Unit: mV/µs
Default= 30.72
SM2_STANDBY, ADDRESS=15, ALL REGISTER BITS R/W
Bit name
NOT USED
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
SM1 OUTPUT VOLTAGE REGULATION VALUE, STANDBY MODE SET
When 0
NOT USED
NOT USED
NOT USED
See Table 9 for SM1, SM2 voltage setting, Power up default=1.8 V
When 1
NOT USED
NOT USED
NOT USED
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SetV1_SM2SL
SetV0_SM2SL
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Table 9. Programmable Settings for SM1 and SM2 (Including STANDBY)
SetV4_
SM
SetV3_
SM
SetV2_
SM
SetV1_
SM
SetV0_
SM
0
0
0
0
0
0
0
0
0
1
0
0
0
1
0
0
0
0
1
0
0
1
0
0
0
0
Vset SM1
Vset SM2
SetV4_
SM
SetV3_
SM
SetV2_
SM
SetV1_
SM
SetV0_
SM
Vset SM1
Vset SM2
0.6
1
1
0
0
0
0
1.24
2.28
0.64
1.08
1
0
0
0
1
1.28
2.36
0.68
1.16
1
0
0
1
0
1.32
2.44
1
0.72
1.24
1
0
0
1
1
1.36
2.52
0
0
0.76
1.32
1
0
1
0
0
1.4
2.6
1
0
1
0.8
1.4
1
0
1
0
1
1.44
2.68
0
1
1
0
0.84
1.48
1
0
1
1
0
1.48
2.76
0
1
1
1
0.88
1.56
1
0
1
1
1
1.52
2.84
0
1
0
0
0
0.92
1.64
1
1
0
0
0
1.56
2.92
0
1
0
0
1
0.96
1.72
1
1
0
0
1
1.6
3
0
1
0
1
0
1
1.8
1
1
0
1
0
1.64
3.08
0
1
0
1
1
1.04
1.88
1
1
0
1
1
1.68
3.16
0
1
1
0
0
1.08
1.96
1
1
1
0
0
1.72
3.24
0
1
1
0
1
1.12
2.04
1
1
1
0
1
1.76
3.32
0
1
1
1
0
1.16
2.12
1
1
1
1
0
1.8
3.4
0
1
1
1
1
1.2
2.2
1
1
1
1
1
0.6
1
A
SM1, SM2 PHASE
S1S2_PHASE1 S1S2_PHASE0
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SMX_SLEW RATE, SMX = SM1 OR SM2
SLEWX_2
SLEWX_1
SLEWX_0
SM1
mV/µs
SM2
mV/µs
0°
0
0
0
0.24
0.48
PHASE
0
0
0
1
90°
0
0
1
0.48
0.96
1
0
180°
0
1
0
0.96
1.92
1
1
270°
0
1
1
1.92
3.84
1
0
0
3.84
7.68
1
0
1
7.68
15.36
1
1
0
15.36
30.72
1
1
1
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FUNCTIONALITY GUIDE – ANALOG TO DIGITAL CONVERTER
10 BIT SUCCESSIVE APPROXIMATION ADC
ADC Input Channels
Trigger Mode
Internal
External
Charge
Current,
Thermistor
temperature,
IC junction
temperature,
RTC_OUT
voltage, OUT
voltage,
Battery
voltage
ANLG1 and
ANLG2
voltages
GPIB, I2C
driven, Repeat
Fixed
internally
Selectable via
I2C
Selectable via
I2C
Conversion
Count
Converter Mode
1, 4, 8, 16, 32,
64, 128, 256
Selectable via
I2C
Trigger Delay
Range
Min Step
Single, Average,
Find max value,
Find min value
0-750 µs,
16 steps
50 µs
Selectable via
I2C
Selectable
via I2C
Wait Time, Multiple
Conversions
Power Up
Default
µs: 20, 40, 60, 80, 160,
240, 320, 640
ADC off
ms: 1.28, 1.92, 2.56,
5.12, 10.24, 15.36, 20.48
Selectable
via I2C
OUT
6 INTERNAL
CHANNELS
Selectable via I2C
SYSTEM POWER BUS
ADC
ANLG 1
ADC
CONTROL
LOGIC
AGND 2
8 CHANNEL
MUX
A/D
CONVERTER
EXTERNAL ANALOG
ANLG 2
INPUT VOLTAGE
ADC _ REF
C17
4.7 mF
A2
A2
Figure 46. Required External Components, Recommended Values, External Connections
ANALOG-TO-DIGITAL CONVERTER
Overview
The TPS65800 has a 10 bit integrated successive approximation A/D, capable of running A/D conversions on
eight distinct channels in a variety of modes. Two of the eight channels are connected to uncommitted pins
ANLG1 and ANLG2, and can be used to convert external voltages. The other six channels monitor system
parameters which are critical to the overall system monitoring. The channel selection is set via I2C.
A dedicated set of I2C registers enables configuration of the ADC to perform a conversion cycle with either a
single conversion or a multiple conversions. The ALU generates a data set containing maximum value detection,
minimum value detection and average value calculation for each conversion cycle. Each cycle can be performed
a single time or multiple times.
Input Channels
The following channels are available for selection via the I2C register ADC_SET bits CHSEL_SET bits:
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Table 10. ADC input channel overview
Channel
Connection
Parameter Sampled
Voltage Range Under
Normal Operating
Conditions
User defined
User defined
Special Features
Full Scale Reading
(Internal reference
selected )
LSB
value
Internal pullup current
source programmable
via I2C: 0/10/50/60 µA
2.535 V
Full scale
reading
÷ 1023
—
2.535 V
Internal 20-µA pullup
current source (ON
only when AC/USB
are present)
2.535 V
CH1
ANLG1 pin
CH2
ANLG2 pin
CH3
ISET1 pin
Voltage proportional to
charge current
CH4
TS pin
Voltage proportional to pack 0 V (short) to 4.7v (no
temperature
thermistor)
CH5
Internal
Voltage proportional to IC
junction
junction temperature
temperature
1.85 V at TJ = 25°C,
–6.5 mV/°C slope typ
—
2.535 V
CH6
RTC_OUT
pin
Internal LDO output voltage
0 V to 3.3 V
—
4.7 V
CH7
OUT pin
System Power bus voltage
0 V to 4.4 V
—
4.7 V
CH8
BAT pin
Battery pack positive
terminal voltage
0 V to 4.4 V
—
4.7 V
0 V (charger off) to
2.525 V (fast charge)
2.535 V
FUNCTIONAL OVERVIEW
The TPS65800 ADC can be subdivided in four sections:
1. Input selection: The input selection section has two major blocks, the input bias control and an 8
channel MUX. The input bias control provides the bias currents that are applied to pins ANLG1 and
ANLG2 and pin TS. The TS pin bias current is fixed (20 µA typ), and the bias currents for pins ANLG1
and ANLG2 are set on I2C register ADC_WAIT.
The TS and ANLG1 pin current sources are automatically enabled when the input power is detected,
providing the required setup to measure a pack thermistor temperature (TS pin) or a battery ID resistor
(ANLG1 pin). ANLG1 and ANLG2 can be used to measure external resistive loads or analog voltages.
The bias current sources are always connected to the OUT pin internally.
The internal MUX connects one of the monitored analog inputs to the ADC engine, following the selection
defined on register ADC_SET.
2. ADC engine: The ADC engine uses an internal or external voltage reference, as defined by the
ADC_REF bit on the ADC_SET control register. If the internal reference is selected ADC_REF is
connected to an internal LDO that regulates the ADC_REF pin voltage to generate the ADC supply and
internal voltage reference. The internal LDO maximum output current is 6 mA typical, and a conversion
should be started only after the external capacitor is fully charged.
If an external reference is used it should be connected to the ADC_REF pin. When an external reference
is selected the internal LDO connected to ADC_REF is disabled. Care must be taken when selecting an
external reference as the ADC reference voltage, as it affects the ADC LSB absolute value.
3. Trigger control and synchronization: The ADC engine starts a conversion of the selected input when
the trigger control circuit sends a start command. The trigger control circuit starts the ADC conversion and
transfers the ADC output data to the arithmetic logic unit (ALU) at the end of the conversion. It also
synchronizes the data transfer from the ALU to the I2C ADC_READING register at the end of a
conversion cycle, and generates the ADC status information sent to the ADC registers.
An ADC engine conversion is triggered by the TPS65800 trigger control circuit using either an internal
trigger or an external trigger. The internal trigger is automatically generated by the TPS65800 at the end
of each ADC engine conversion, following the timing parameters set on I2C registers ADC_SET,
ADC_DELAY and ADC_WAIT.
The GPIO3 pin can be used as an external trigger if the bit ADC_TRG_GPIO3 is set HI, in the I2C register
ADC_DELAY. In the external trigger mode a new conversion is started after the GPIO3 pin has an edge
transition, following the timing parameters set on I2C registers ADC_SET, ADC_DELAY and ADC_WAIT.
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4. Arithmetic Logic Unit (ALU): The ALU performs mathematical operations on the ADC output data as
defined by the I2C ADC_READING registers. It executes average calculations or minimum /maximum
detection. The result of the calculations is stored in a 11 bit accumulator register (1 bit allocated for
carry-over). The accumulator value is transferred to the I2C data register at the end of a conversion cycle.
A simplified block diagram for the ADC is shown in Figure 47.
TPS65800
ANLG 1/
ANLG 2 BIAS
SELECTION
ADC SUPPLY
AND
REFERENCE
SELECTION
I2C
BIAS CONTROL
ADC REFERENCE
AND SUPPLY
SELECTION
OUT
ADC_REF
4.7 mF
SUPPLY
ANLG1
REF
10 BIT SUCCESSIVE
APROXIMATION ADC
ANLG2
ISET1
START
TS
TJ
CURRENT SAMPLE
A2
DONE
8 CHANNEL
MUX
ARITHMETIC LOGIC
UNIT
RTC_OUT
TRIGGER CONTROL
AND
SYNCHRONIZATION
OUT
BAT
ADC
CHANNEL
SELECTION
ADC CONFIGURATION :
TRIGGER, HOLDOFF, REPEAT
MODES
DELAY AND WAIT TIMING
ACCUMULATOR
ALU MODE :
SINGLE ,
AVERAGE ,
MIN,, MAX
TO I2C:
STATUS AND
CONVERSION
DATA
I2C
Figure 47. ADC Simplified Block Diagram
ADC Conversion Cycle
A conversion cycle includes all the steps required to successfully sample the selected input signal and transfer
the converted data to the I2C, generating an interrupt request to the host ( pin: HI→LO). The number of
individual conversions (samples) in a conversion cycle is defined by the I2C ADC_SET register bits
READ_MODE settings, and can range from a single sample to 256 samples. The conversion cycle settings for
the ALU is defined by register ADC_READING and it can be set to average, maximum value detection, minimum
value detection or no processing (ADC engine output loaded in the accumulator directly).
The conversion cycle starts with the first sampling and ends when:
• The required ALU operations are performed on the final sample, and
• The ALU accumulator data is transferred to the I2C ADC_READING register, and
• The register bit ADC_STATUS in the ADC_READING register is set to LO.
A conversion cycle is always started by the external host when the ADC_EN bit in the ADC_SET register is
toggled from LO to HI by a I2C write operation. Resetting the ADC_EN bit to LO before the current conversion
cycle ends (INT: LO → HI, ADC_STATUS bit set to LO) is not recommended, as the ADC keeps its current
configuration until the current conversion cycle ends.
At the end of a conversion cycle the output data is stored at registers in the ALU block. The ADC_STATUS bit is
set to LO ( DONE ) and an interrupt is generated (INT pin: HI→LO ) if the ADC_STATUS bit is unmasked, at the
interrupt masking registers INT_MASK. It should be noted that the minimum, maximum and average values are
ALWAYS calculated by the ALU for each conversion cycle.
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The value loaded in the I2C registers ADC READING_HI and ADC READING_LO at the end of a conversion
cycle is defined by control bits ADC_READ0 and ADC_READ1 in register ADC READING_HI. The average,
minimum, maximum and last sample values for a conversion cycle can be read if the external host executes an
I2C write operation, changing the values of bits ADC_READ0 and ADC_READ1, followed by an I2C read
operation on registers ADC READING_HI and ADC READING_LO. The minimum, maximum, average, and last
values have the same value if a conversion cycle with only one sample is executed.
The ADC_READ0 and ADC_READ1 bits can not be modified during the execution of a conversion cycle. A new
conversion cycle should be started only after the current conversion cycle is completed, by toggling the ADC_EN
bit from HI to LO and HI again.
External Trigger Operation
The trigger control circuit can be programmed to use an external signal to start a conversion. The TPS65800
GPIO3 input is configurable as an ADC trigger, with ADC conversion starting on either a rising edge or falling
edge. When using an external trigger the trigger delay, trigger wait time delay and trigger holdoff mode can be
programmed using I2C registers.
The procedure to start an externally-triggered conversion cycle has the following steps:
1. Verify that the current conversion cycle has ended (ADC_STATUS=LO, I2C register ADC_READING_HI)
2. Set ADC_EN=LO
3. Configure ADC sampling mode, ALU mode, trigger parameters, etc.
4. Set ADC_EN=HI
After step 4 the ADC is armed, waiting for an external trigger detection to start a conversion cycle. Similarly to
the non-triggered mode, the ADC configuration should not be modified until the current conversion cycle ends.
Note that in the external trigger mode the current cycle does not end if the converter is armed and an external
trigger is not detected.
Detecting an External Trigger Event
An external trigger event is detected when the GPIO3 input has an edge that matches the edge detection
programmed in the EDGE bit, at the I2C register ADC_DELAY. The internal ADC trigger can be delayed with
respect to the external trigger signal edge. The delay time value is set by the ADC_DELAY register bits
DELAY_n, and can range from 0 µs (no delay) to 750 µs. A conversion is started only if the external trigger
remains at its active level when the delay time expires, as shown in Figure 48. In a positive-edge detection the
active trigger level is HI; in a negative-edge detection the active trigger level is LO.
GPIO 3
INTERNAL ADC
CONVERSION START
CONVERTER
MODE
CONVERTING
ARMED
TDLY(TRG)
TDLY(TRG)
Figure 48. ADC Conversion Triggerd by GPIO3 Positive Edge-Triggered Active-Level HI
Executing Multiple-Sample Cycles With an External Trigger
When executing conversion cycles that require multiple samples it may be desirable to synchronize the input
signal conversion using either an external trigger that has a periodic repetition rate or an external asynchronous
trigger that indicates when the external input signal being converted is valid. The TPS65800 has additional
operating modes and timing parameters that can be programmed using the I2C to configure multiple sample
conversion cycles.
In multiple sample cycles the host can select the wait time between samples using the bits WAITn in the
ADC_WAIT register to set the wait time between samples. The wait time is measured between the end of a
conversion and the start of a new conversion.
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With the default power-up settings (HOLDOFF=LO, ADC_DELAY register), the TPS65800 executes a
multiple-sample conversion cycle if the first sample is taken when the trigger is at its active level. Subsequent
samples are converted at the end of the wait time, even if the trigger returns to the non-active level. The external
trigger level edge is ignored until the current conversion cycle ends.
CONVERSION CYCLE
GPIO 3
ON
INTERNAL ADC
OFF
CONVERSION STATUS
tWAIT(TRG)
tDLY(TRG)
LAST
SAMPLE
FIRST
SAMPLE
Figure 49. ADC Conversion Triggerd by GPIO3 Positive Edge-Triggered Active-Level Hi, Holdoff = LC
If the sample conversion needs to be synchronized with an external trigger, during multiple sample conversion
cycles, the control bit HOLDOFF should be set to HI. When the holdoff mode is active, the internal trigger starts
a sample conversion only if the external trigger was detected and is at its active level at the end of the wait time,
as shown in Figure 50.
CONVERSION CYCLE
GPIO 3
ON
INTERNAL ADC
CONVERSION STATUS
OFF
TDLY(TRG)
TDLY(TRG)
TWAIT(TRG)
FIRST
SAMPLE
LAST
SAMPLE
Figure 50. ADC Conversion Triggered by GPIO3 Positive Edge-Triggered Active-Level HI;
Holdoff = HI, Four Sample Cycles
When the multiple sample cycles are executed the host must configure the maximum and minimum limits for the
ADC output using registers DLOLIM1, DLOLIM2, DHILIM1 and DHILIM2. A conversion cycle ends if any
individual conversion result exceeds the maximum limit value or is below the minimum limit value. When an out
of limit conversion is detected an interrupt is sent to the host, and the ADC_STATUS bit on register ADC
READING_HI is set to DONE.
Continuous Conversion Operation (Repeat Mode)
The TPS65800 ADC can be set to operate in a continuous conversion mode, with back-to-back conversion
cycles executed. The REPEAT mode is targeted at applications where an input is continuously monitored for a
period of time, and the host must be informed if the monitored input is out of the range set by I2C registers
DLOLIM1, DLOLIM2, DHILIM1 and DHILIM2. In REPEAT mode each conversion is started when the ADC
trigger (internal or external) is detected, and a new conversion cycle is started when the current conversion cycle
ends. All the trigger and sampling modes available for normal conversion cycles are available in repeat mode.
Executing I2C read operations to get the ADC readings for average, minimum, maximum and last sample values
is possible in REPEAT mode. However, this is not a recommended operation, as the REPEAT mode does not
generate a DONE status flag making it difficult to synchronize the ADC data reading to the end of a conversion
cycle.
The recommended use of the REPEAT mode is:
1. Configure the ADC conversion cycle: trigger mode, sample mode, select input signal, etc.
2. Configure the HI and LO limits for the ADC readings
3. Set the ADC_DELAY register bit REPEAT to HI
4. Toggle ADC_DELAY register bit ADC_EN bit from LO to HI
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5. Monitor the INT pin. An interrupt triggered by ADC_STATUS=LO indicates that the selected input signal is
out of range
To exit the continuous mode the host must follow the steps below, if external trigger mode was set:
1. Exit external trigger mode
2. Set REPEAT bit to LO, effectively terminating the repeat mode. This generates an additional conversion;
at the end of this conversion the ADC is ready for a new configuration.
3. Set ADC_EN to LO, after on-going conversion ends
To exit the continuous mode the host must follow the steps below, if internal trigger mode was set:
1. Set REPEAT bit to LO, effectively terminating the repeat mode.
2. Set ADC_EN to LO, after on-going conversion ends
ADC Input Signal Range Setting
The registers DHILIMn and DLOLIMn can be used by the host to set maximum and minimum limits for the DAC
engine output. At the end of each conversion the ADC output is checked for the maximum and minimum limits,
and a status flag is set if the converted data exceeds the high limit or is under the low limit. In multiple sample
operation the converted data range is checked when all programmed samples have been converted.
The host can mask or unmask interrupts caused by the ADC range status bits using the INT_MASKn registers.
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ADC State Machine
The ADC state machine with all the trigger and operation modes is shown in Figure 51.
NO
HOST STARTS NEW
CONVERSION
CYCLE BY SETTING
ADC_EN=HI
EXTERNAL
TRIGGER
ADC
ENABLED
(I2C) ?
TPS
65800 READY
FOR NEW
CONVERSION
CYCLE
YES
NO,
ADC+EN=LO,
NEED TO
RECONFIGURE
ADC
PARAMETERS
TRIGGER
EDGE
DETECT
NO
LOAD ADC
CONFIGURATION
DATA FROM I 2C
YES
START TRIGGER
DELAY
NO
TRIGGER
DELAY
OVER
NO, OPPOSITE
TRIGGER EDGE
HAPPENED
BEFORE DELAY
TIME
FALLING
EDGE
TRIGGER
EDGE
MODE
RISING
EDGE
TRIGGER
VALID
YES
TRIGGER
HI
ALU
RESET
HOLDOFF
ON
TRIGGER MODE,
TRIGGER DELAY
SAMPLE WAIT TIME,
HOLDOFF MODE
REPEAT ON/OFF
ALU MODE : AVG /MAX/MIN
NUMBER OF SAMPLES
ADC INPUT RANGE
ADC CHANNEL
I2C WRITE OPERATION
CONFIGURES NEXT
CONVERSION CYCLE
ADC_EN=LO
NO
TRIGGER
LO
NO, HOST ENDS
CURRENT
CONVERSION
CYCLE SETTING
ADC_EN=LO
NO
YES, CURRENT
CONVERSION
CYCLE STILL
ACTIVE,
ADC_EN = HI
YES, CHECK
TRIGGER
NO
1) SET ADC
BUSY STATUS
2) START
CONVERSION
ADC
ENABLED
(I2C) ?
YES
ADC
ENABLED
(I2C) ?
ADC CONVERSION
COMPLETE
NO, SEND
DATA
TO I2C
1) LOAD DATA IN
ALU
2) ALU OUTPUT
STORED IN
ACCUMULATOR
WAIT TIME
0 µs to 20.5 msec
ALU OUTPUT
DATA READY
YES
N
CONVERSIONS
?
ALU
DATA OUT OF
RANGE
NO
NTH
CONVERSION
DONE
REPEAT
MODE
YES FAULT
DETECTED
YES
NO
NO
YES
1) SET ADC_HI OR
ADC_LO FAULT
2) SET ADC STATUS
TO DONE
3) INT SENT TO HOST
IF NON-MASKED
NO, SEND
DATA
TO I2C
1 ) LOAD I2C DATA
REGISTER WITH
ALU DATA
2) SET ADC STATUS
TO DONE
3) INT SENT TO HOST
IF NON-MASKED
CURRENT
CYCLE ENDS
Figure 51. Trigger and Operation Modes for the ADC State Machine
BATTERY DETECTION CIRCUIT
The ANLG1 pin has an internal current source connected between OUT and ANLG1, which is turned on
automatically when the OUT pin voltage exceeds the minimum system voltage set by the SYS_IN pin external
resistive divider. The current levels for ANLG1 pin can be programmed via I2C register ADC_WAIT, bits
BATID_n. An integrated switch discharges the BAT pin to AGND1 when V(ANLG1)> V(OUT) – V(NOBATID),
enabling implementation of a battery removal function if an external pack resistor ID is connected between
ANLG1 and ground.
The ANLG1 pin may be used to monitor other parameters than a pack ID resistor. When ANLG1 pin is used as
a generic ADC analog input V(ANLG1) should never exceed V(OUT) – V(NOBATID), to avoid undesired battery
discharge caused by activation of the battery pin discharge circuit.
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ADC – I2C REGISTERS
The I2C registers that control ADC-related functions are shown below. The HEX address for each register is
shown by the register name, together with the R or W functionality for the register bits. Default, initial power-up
values are shown in bold. In the timing equations, replace Bn with 1 for HI state, and 0 for LO state.
B7
B6
B5
B4
B3
B2
CHSEL1_SET
CHSEL0_SET
B1
B0
ADC_SET, ADDRESS = 1E, ALL BITS R/W
Bit Name
ADC_ENABLE
ADC_REF_EN
Function
ADC ON/OFF
CONTROL
ADC
REFERENCE
SELECTION
When 0
OFF
Internal
When 1
ON
External
CHSEL2_SET
READ_MODE2 READ_MODE1
ADC CHANNEL SELECTION
000 = ANLG1
011 = V(TS)
001 = ANLG2
100 = Tj
010 = V(ISET1) 101 =
V(RTC_OUT)
READ_MODE0
ADC SAMPLING SETTINGS
110 = V(OUT)
111 = V(BAT)
Default =
ANLG1
000 = 1
001 = 4
010 = 8
011 = 16
100 = 32
101 = 64
110 = 128
111 = 256
Default = 1
ADC READING_HI, ADDRESS = 1F, BITS B3/B4 R/W, ALL OTHER BITS READ ONLY
Bit Name
NOT USED
NOT USED
CURRENT
CONVERSION
STATUS
NOT USED
NOT USED
ALU OUTPUT DATA
SELECTION
When 0
DONE
NOT USED
NOT USED
When 1
BUSY
NOT USED
NOT USED
00=LAST 10 = MAXIMUM
01=AVERAGE 11 = MINIMUM
Default= LAST
Function
ADC_STATUS
ADC_READ1
ADC_READ0
D10
ADC
AVERAGE
CARRYOVER
BIT
D9_MSB
D8
ADC CONVERSION OUTPUT
BITS
VALID ONLY AFTER ADC
CONVERSION ENDS SEE
ADC_READING_LO
ADC READING_LO, ADDRESS = 20, READ ONLY
Bit Name
D7
D6
Function
Value
D5
D4
D3
D2
D1
D0_LSB
ADC CONVERSION OUTPUT BITS, VALID ONLY AFTER ADC CONVERSION ENDS
VALUE=[B10*512 + B9*256 + B8*128 + B7*64 + B6*32 + B5*16 + B4*8 + B3*4 + B2*2 + B1] * [ VRNG(CHn) / 1023]; Unit=Volts,
The LSB bit value is proportional to the ADC reference voltage - See VRNG(CHn) in electrical parameters
DHILIM1, ADDRESS = 21, ALL BITS R/W
Bit Name
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
RESERVED
DHILIM10
DHILIM9
DHILIM8
ADC MAX INPUT LIMIT RANGE SETTING (3
MSBs)
DHILIM2, ADDRESS = 22, ALL BITS R/W
Bit Name
DHILIM7
DHILIM6
Function
DHILIM5
DHILIM4
DHILIM3
DHILIM2
DHILIM1
DHILIM0_LSB
DLOLIM9
DLOLIM8
ADC MAX INPUT LIMIT RANGE SETTING (8 LSBs)
DLOLIM1, ADDRESS = 23, ALL BITS R/W
Bit Name
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
RESERVED
DLOLIM10
ADC MIN INPUT LIMIT RANGE SETTING (3 MSBs)
DLOLIM2, ADDRESS = 24, ALL BITS R/W
Bit Name
DLOLIM7
DLOLIM6
Function
DLOLIM5
DLOLIM4
DLOLIM3
DLOLIM2
DLOLIM1
DLOLIM0_LSB
Delay_1
Delay_0
ADC MIN INPUT LIMIT RANGE SETTING (8 LSBs)
ADC_DELAY, ADDRESS = 25,ALL BITS R/W
Bit Name
ADC_TRG_GPIO3
EDGE _GPIO3
HOLDOFF
REPEAT
Function
USE GPIO3 AS
ADC TRIGGER
GPIO3
TRIGGER
MODE
ADC
HOLDOFF
ON/OFF
CONTROL
REPEAT
MODE
ON/OFF
Delay_3
ADC EXTERNAL TRIGGER DELAY SETTING
Delay_2
When 0
OFF
Falling Edge
OFF
OFF
When 1
ON
Rising Edge
ON
ON
tDLY(TRIG)= B4*400 + B3 * 200 + B2*100 + B1* 50, Units=µs Default=0
µs
BATIDI_D1
BATIDI_D0
ADC_WAIT, ADDRESS = 26, ALL BITS R/W
Bit Name
Function
When 0
When 1
74
ADC_cH2I_D1
ADC_cH2I_D0
ANLG2 PULLUP CURRENT
SOURCE VALUE
ANLG1 PULLUP CURRENT
SOURCE VALUE
11:60 µA, 10:50 µA, 01:10 µA, 00: 0
Default= 00
11:60 µA, 10:50 µA, 01:10 µA,
00: WEAK PULLUP
Default: 00
WAIT_D3
WAIT_D2
WAIT_D1
WAIT_LSB
ADC SAMPLE WAIT TIME, MULTIPLE SAMPLES MODE
0000 = 0
0001 = 0.02
0010 = 0.04
0011 = 0.06
Units = ms
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0100
0101
0110
0111
= 0.08
= 0.16
= 0.24
= 0.32
1000 = 0.64
1001 = 1.28
1010 = 1.92
1011 = 2.56
1100 = 5.12
1101 = 10.24
1110 = 15.36
1111 = 20.48
Default = 0
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FUNCTIONALITY GUIDE — LED AND PERIPHERAL DRIVERS
WHITE LED CONSTANT CURRENT DRIVER
Driver
PWM
SM3
Duty Cycle
Range
# of Steps
Off (0%),
0.4% -99.6%
Set via I2C
256
Output
Voltage
LED Current
5 V–25 V
Io(Typ)
Max
Acc (%)
Set by external resistor
25 mA
25
Eff (%)
Power Up
Default
80
Off (0%)
OPEN DRAIN PWM DRIVERS
Driver
PWM Freq (kHz)
PWM Duty Cycle
Range
# of Steps
Min Step
Io(max)
mA
Power Up Default
PWM
0.5/1/1.5/2/3/ 4.5/7.8/15.6
Set via I2C
Off (0%),
6.25% to 100
Set via I2C
8
6.25%
150
Off(0%)
LED_PWM
15.625 or 23.4 , set via I2C
Off(0%),
0.4% to 99.6%
Set via I2C
256
0.4%
150
Off (0%)
RGB OPEN DRAIN LED DRIVER
Driver
RED,
GREEN,
BLUE
Flash Period (same for RGB)
Flash On time (same for RGB)
Brightness
(Individual R/G/B Control)
Range
# of
Steps
Min Step
Range
# of
Steps
Min Step
Duty (%)
# of
Steps
Min
Steps
No flash,
or 1–8 s
Set via I2C
16
0.5 s
0.1–0.6 s
Set via I2C
8
0.1 s
Off (0%),
3.125 to
96.87
Set via I2C
32
3.125%
Io mA
Power Up
Default
0/4/8/12
Flash Off, 0
mA,
0%
brightness
duty cycle
TPS65800
OUT
DISPLAY AND I/O
SM3_SW
4.7 mH
L3
WHITE LED
DRIVER
SM3
FB3
PGND3
PWM
DRIVER
LSM3
D1
RFB3
C18
100 pF
10 W
P3
WHITE LEDS
PWM
EXTERNAL
PERIPHERALS
LED_PWM
RED
RGB
DRIVER
C27
1 mF
GREEN
BLUE
AGND0
RGB LED
A0
Figure 52. Required External Components, Recommended Values, External Connections
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WHITE LED CONSTANT CURRENT DRIVER
The TPS65800 has an integrated boost converter (SM3) that is optimized to drive white LEDs connected in a
series configuration. Up to six series white LEDs can be driven, with programmable current and duty cycle
adjustable via a dedicated I2C register.
The SM3 boost converter (SM3) has a 30-V, 500-mA, low-side integrated power stage switch that drives the
external inductor. Another integrated 30-V, 25-mA switch (LED switch) is used to modulate the brightness of the
external white LEDs. A simplified block diagram is shown in Figure 53
LSM3
3.3 mH
OUT
TPS65800
INDUCTOR PEAK
CURRENT
DETECTION
L3
+
_
SOFT 500 mA
START
OFF
CONTROL LOGIC AND
MINIMUM OFF TIME
MAXIMUM ON TIME
ON EN
D1
OFF
C27
1 mF
POWER
STAGE
SWITCH
GATE
DRIVE
PGND3
OUTPUT OVP
DETECTION
+
SM3
_
28V
P3
SM3_SW
ON
LED SWITCH
FREQUENCY
AND DUTY
CYCLE
I2C REGISTER
DUTY CYCLE
CONTROL
GATE
DRIVE
LED
SWITCH
LED LOW CURRENT
_
DETECTION
+
FB3
RFB3
250 mV
10 W
P3
Figure 53. Simplified Block Diagram
The SM3 converter operates like a standard boost converter. The LED current is defined by the value of the
external resistor RFB3, connected from pin FB3 to AGND1. The integrated power stage switch control monitors
the LED switch current (FB3) and the integrated power stage switch current, implementing a topology that
effectively regulates the LED current independently of the input voltage and number of LEDs connected. The
high voltage rating of the integrated switches enables driving up to six white LEDs, connected in a series
configuration.
The internal LED switch, in series with the external LEDs, disconnects the LEDs from ground during shutdown.
In addition, the LED switch is driven by a PWM signal that sets the duty cycle, enabling adjustment to the
average LED current by modifying the settings of the I2C register SM3_SET. With this control method, the LED
brightness depends on the LED switch duty cycle only, and is independent of the PWM control signal.
The duty cycle control used in the SM3 converter LED switch is implemented by generating a burst of high
frequency pulses, with a pattern that is repeated periodically. For a duty cycle of 50%, all of the high frequency
pulses have a 50% duty cycle. The duty cycle control sets individual pulses to 100% duty cycle when increasing
the LED_PWM output duty cycle; for decreasing LED_PWM output duty cycles, individual pulses are set to 0%
duty cycle. An example of distinct duty cycles is shown in Figure 54, the sum of the individual pulses on/off time
over the repetition period are equivalent to the duty cycle obtained with traditional single-pulse duty cycle
circuits.
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SM3 CONVERTER
50% DUTY CYCLE
SM3 CONVERTER
<50% DUTY CYCLE
SM3 CONVERTER
>50% DUTY CYCLE
REPETITION PERIOD
Figure 54. Example of Distinct Duty Cycles
The repetition period can be set using the register SOFT_RESET control bit SM3_LF_OSC to either 180 Hz (HI)
or 122 Hz (LO). Each repetition period has a total of 256 pulses, enabling a resolution of 0.4% when
programming the duty cycle.
SM3 Control Logic Overview
The SM3 boost converter operates in a pulse frequency modulation (PFM) scheme with constant peak current
control. This control scheme maintains high efficiency over the entire load current range and enables the use of
small external components, as the switching frequency can reach up to 1 MHz depending on the load
conditions. The LED current ripple is defined by the external inductor size.
The converter monitors the sense voltage at pin FB3, and turns on the integrated power stage switch when
V(FB3) is below the 250-mV (typ) internal reference voltage and the LED Switch is ON, starting a new cycle. The
integrated power switch turns off when the inductor current reaches the internal 500-mA (typ) peak current limit,
or if the switch is on for a period longer than the maximum on-time of 6 µs (typ). The integrated power switch
also turns off when the LED switch is set to OFF. As the integrated power switch is turned off, the external
Schottky diode is forward biased, delivering the stored inductor energy to the output. The main switch remains
off until the FB3 pin voltage is below the internal 250-mV reference voltage and the LED switch is turned ON,
when it is turned on again.
This PFM peak current control scheme sets the converter in discontinuous conduction mode (DCM), and the
switching frequency depends on the inductor, input/output voltage and LED current. Lower LED currents reduce
the switching frequency, with high efficiency over the entire LED current range. This regulation scheme is
inherently stable, allowing a wide range for the selection of the inductor and output capacitor.
Peak Current Control (Boost Converter)
The SM3 integrated power stage switch is turned on until the inductor current reaches the DC current limit
IMAX(L3) (500 mA, typ). Due to internal delays, typically around 100 ns, the actual current exceeds the DC current
limit threshold by a small amount. The typical peak current limit can be calculated as shown in Equation 8
V(OUT)
V(OUT)
I P(typ) + I MAX(L3) )
100 ns, or : I P(typ) + 500 mA )
100 ns
L
L
(8)
The current overshoot is directly proportional to the input voltage, and inversely proportional to the inductor
value.
Soft Start
All inductive step-up converters exhibit high in-rush current during start-up. If no special precautions are taken,
voltage drops can be observed at the input supply rail during start-up, with unpredictable results in the overall
system operation.
The SM3 boost converter limits the inrush current during start-up by increasing the current limit in three steps:
1. 125 mA (typ),
2. 250 mA (typ) and
3. 500 mA (typ)
The two initial steps (125 mA and 250 mA) are active for 256 power stage switching cycles.
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Enabling the SM3 Converter
The SM3_SET I2C register controls the SM3 LED switch duty cycle. If the register is set to all zeros SM3 is set
to OFF mode. When the host writes a value other than 00 in SM3_SET the SM3 converter is enabled, entering
the soft start phase and then normal operation. The SM3 converter can operate with duty cycles varying from
0.4% to 99.6%, with LED switch frequencies of 122 Hz or 180 Hz. The LED switch operating frequency is set by
bit SM3_LF, in the SOFT_RESET register.
Overvoltage Protection
The output voltage of the boost converter is sensed at pin SM3, and the integrated power stage switch is turned
OFF when V(SM3) exceeds the internal overvoltage threshold VOVP3. The converter returns to normal operation
when V(SM3) < VOVP3– VHYS(OVP3).
Under Voltage Lockout Operation
When the TPS65800 enters the UVLO mode, the SM3 converter is set to OFF mode with the power stage
MOSFET switch and the LED switch open (off).
Thermal Shutdown Operation
When the TPS65800 enters the thermal shutdown mode, the SM3 converter is set to OFF mode with the power
stage MOSFET switch and the LED switch open (off).
PWM DRIVERS
PWM Pin Driver
The TPS65800 offers one low-frequency, open-drain PWM driver, capable of driving up to 150 mA. The PWM
frequency and duty cycle are defined by the PWM I2C register settings. The PWM parameters are set in I2C
register PWM. Available frequency values range from 500 Hz to 15 kHz, with 8 frequency values and 16 duty
cycle options (6.25% each).
LED_PWM Pin Driver
The TPS65800 has another PWM driver output (pin LED_PWM), which is optimized to drive a backlight LED.
The LED_PWM driver controls the external LED current intensity using a pulse-width control method, with duty
cycle being set by the I2C register LED_PWM.
The pulse width method implemented generates a burst of high frequency pulses, with a pattern that is repeated
periodically. For a duty cycle of 50%, all of the high -frequency pulses have a 50% duty cycle. The duty cycle
control sets individual pulses to 100% duty cycle when increasing the LED_PWM output duty cycle; for
decreasing LED_PWM output duty cycles individual pulses are set to 0% duty cycle. An example of distinct duty
cycles is shown in Figure 55; the sum of the individual pulses on/off time over the repetition period is equivalent
to the duty cycle obtained with traditional single-pulse duty cycle circuits.
LED_PWM, 50% DUTY CYCLE
LED_PWM, <50% DUTY CYCLE
LED_PWM, >50% DUTY CYCLE
REPETITION PERIOD
Figure 55. Example of Distinct Duty Cycles
The repetition period can be set using the register SOFT_RESET control bit SM3_LF_OSC to either 183 Hz (HI)
or 122 Hz (LO). Each repetition period has a total of 256 pulses, enabling a resoltuion of 0.4% when
programming the duty cycle. The LED_SET register enables control of the duty cycle via I2C, with duty cycle
ranging from 0.4% to 99.6%. Setting the LED_SET register to all zeros forces the LED_PWM pin to 0% duty
cycle (OFF).
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RGB Driver
The TPS65800 has a dedicated driver for an RGB external LED. Three outputs are available (pins RED,
GREEN, BLUE), with common settings for operation mode (flash on/off, flash period, flash on time), LED current
and phase delay between outputs. The TPS65800 RGB driver continually flashes the external LEDs connected
to the RED, GREEN and BLUE pins using the flash operation parameters defined in register RGB_FLASH.
The currents for the external LEDs can be programmed via I2C, and external resistors are not required to limit
the LED current. However, they can be added to set the LED current if the available I2C values are not
compatible with the current application, as shown in the circuit below:
OUT
RED
RRED
RGRN
RBLUE
FLASH
CONTROL
ILEDR
GREEN
LED
CURRENT
SETTINGS
RGB
DUTY
CYCLE
CONTROL
LED
CONTROL
ILEDG
LOGIC
BLUE
ILEDB
Figure 56. Limiting the External LED Current
The flashing-mode parameters defined in register RGB_FLASH enable setting the flashing period from 1 to 8
seconds in 0.5-s steps, or to continuous operation. Flashing operation is enabled by setting the FLASH_EN bit in
register RGB_FLASH to HI. This bit must be set HI to enable the RGB current-sink channels.
Each driver has an individual duty cycle control. The duty cycle modulation method used is similar to the
PWM_LED duty cycle control, with high frequency pulses being generated when the driver (RED, GREEN, or
BLUE pins) is ON. The repetition period for the RGB drivers has a total of 32 pulses, enabling a 3.125%
resolution when programming the individual RED, GREEN and BLUE drivers duty cycles. The duty cycles for
each driver can be set individually using control bits on registers RGB_RED, RGB_GREEN and RGB_BLUE.
The RGB drivers can be programmed to sink 4, 8, or 12 mA, with no external current limiting resistor.
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White LED, PWM Drivers — I2C Registers
The I2C registers that control LED AND PWM driver related functions are shown below. The HEX address for
each register is shown by the register name, together with the R or W functionality for the register bits. Shaded
values indicate default initial power-up values. In the equations replace Bn with 1 for HI state, and 0 for LO state.
B7
B6
B5
B4
B3
B2
B1
B0
SM3_I4 set
SM3_I3 set
SM3_I2 set
SM3_I1 set
SM3_I0 set
FLASH_PER1
FLASH_PER0
SM3_SET, ADDRESS=16, ALL BITS R/W
Bit Name
SM3_I7 set
SM3_I6 set
SM3_I5 set
Function
SM3 DUTY CYCLE CONTROL
Value
See Table 11 for SM3 duty cycle settings, default = 0 (OFF)
RGB_FLASH, ADDRESS= 17, ALL BITS R/W
Bit Name
FLASH_EN
Function
FLASH MODE
ON/OFF CTRL
FLASH_ON2
FLASH MODE ON TIME
FLASH_ON1
FLASH_ON0
FLASH_PER3
FLASH_PER2
FLASH MODE PERIOD
When 0
OFF
ON
See Table 12 for RGB ON TIME settings,
default=0.1
See Table 12 for RGB FLASH settings, default = 1
When 1
RGB_RED, ADDRESS=18, ALL BITS R/W
Bit Name
Function
When 0
RGB_ISET1
RGB_ISET0
PHASE
PWMR_D4
PWMR_D3
PWMR_D2
PWMR_D1
RGB LED CURRENT SETTINGS
PHASE
CONTROL
REG DRIVER DUTY CYCLE CONTROL
00= 0 10= 8 mA
01= 4 mA 11=12 mA
GREEN out of
Φ with RED &
BLUE
See Table 12 for RGB_RED DUTY settings, default = 0
PWMR_D0
BLUE out of Φ
with RED &
GREEN
When 1
RGB_GREEN, ADDRESS=19, ALL BITS R/W
Bit Name
NOT USED
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
PWMG_D4
PWMG_D3
GREEN DRIVER DUTY CYCLE CONTROL
PWMG_D2
PWMG_D1
PWMG_D0
Value
NOT USED
NOT USED
NOT USED
See Table 12 for RGB_GREEN DUTY settings, default = 0
RGB_BLUE, ADDRESS=1A, ALL BITS R/W
Bit Name
NOT USED
NOT USED
NOT USED
Function
NOT USED
NOT USED
NOT USED
PWMB_D4
PWMB_D3
BLUE DRIVER DUTY CYCLE CONTROL
PWMB_D2
PWMB_D1
Value
NOT USED
NOT USED
NOT USED
See Table 12 for RGB_BLUE DUTY settings, default = 0
PWMB_D0
PWM, ADDRESS=1D, ALL BITS R/W
Bit Name
PWM_EN
Function
PWM ON/OFF
CONTROL
When 0
Disabled
When 1
Enabled
PWM1_F2
PWM_F1
PWM_F0
PWM_D3
PWM DRIVER FREQUENCY SETTINGS
000 = 15.6 kHz
001 = 7.8 kHz
010 = 4.5
kHz
011 = 3 kHz
100 = 2 kHz
101 = 1.5 kHz
110 = 1 kHz
111 = 500 Hz
Default = 15.6
kHz
LPWM_5 set
LPWM_4 set
PWM_D2
PWM_D1
PWM_D0
PWM DRIVER DUTY CYCLE SETTINGS
See Table 13 for PWM DUTY settings, default = 0.0625
LED_PWM, ADDRESS=27, ALL BITS R/W
Bit Name
Function
Value
80
LPWM_7 set
LPWM_6 set
LPWM_3 set
LPWM_2 set
LED_PWM DRIVER DUTY CYCLE CONTROL
See Table 11 for LED_PWM DUTY settings, default=0 (OFF)
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LPWM_1 set
LPWM_0 set
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SLVS606C – SEPTEMBER 2005 – REVISED FEBRUARY 2007
Table 11. SM3 Duty Cycle Settings
Dec
B7–B0
Dcpu
Dec
B7–B0
Dcpu
Dec
B7–B0
Dcpu
Dec
B7–B0
Dcpu
Dec
B7–B0
Dcpu
0
0000 0000
–
52
0011 0100
0.203
104
0110 1000
0.406
156
1001 1100
0.609
208
1101 0000
0.813
1
0000 0001
0.004
53
0011 0101
0.207
105
0110 1001
0.410
157
1001 1101
0.613
209
1101 0001
0.816
2
0000 0010
0.008
54
0011 0110
0.211
106
0110 1010
0.414
158
1001 1110
0.617
210
1101 0010
0.820
3
0000 0011
0.012
55
0011 0111
0.215
107
0110 1011
0.418
159
1001 1111
0.621
211
1101 0011
0.824
4
0000 0100
0.016
56
0011 1000
0.219
108
0110 1100
0.422
160
1010 0000
0.625
212
1101 0100
0.828
5
0000 0101
0.020
57
0011 1001
0.223
109
0110 1101
0.426
161
1010 0001
0.629
213
1101 0101
0.832
6
0000 0110
0.023
58
0011 1010
0.227
110
0110 1110
0.430
162
1010 0010
0.633
214
1101 0110
0.836
7
0000 0111
0.027
59
0011 1011
0.230
111
0110 1111
0.434
163
1010 0011
0.637
215
1101 0111
0.840
8
0000 1000
0.031
60
0011 1100
0.234
112
0111 0000
0.438
164
1010 0100
0.641
216
1101 1000
0.844
9
0000 1001
0.035
61
0011 1101
0.238
113
0111 0001
0.441
165
1010 0101
0.645
217
1101 1001
0.848
10
0000 1010
0.039
62
0011 1110
0.242
114
0111 0010
0.445
166
1010 0110
0.648
218
1101 1010
0.852
11
0000 1011
0.043
63
0011 1111
0.246
115
0111 0011
0.449
167
1010 0111
0.652
219
1101 1011
0.855
12
0000 1100
0.047
64
0100 0000
0.250
116
0111 0100
0.453
168
1010 1000
0.656
220
1101 1100
0.859
13
0000 1101
0.051
65
0100 0001
0.254
117
0111 0101
0.457
169
1010 1001
0.660
221
1101 1101
0.863
14
0000 1110
0.055
66
0100 0010
0.258
118
0111 0110
0.461
170
1010 1010
0.664
222
1101 1110
0.867
15
0000 1111
0.059
67
0100 0011
0.262
119
0111 0111
0.465
171
1010 1011
0.668
223
1101 1111
0.871
16
0001 0000
0.063
68
0100 0100
0.266
120
0111 1000
0.469
172
1010 1100
0.672
224
1110 0000
0.875
17
0001 0001
0.066
69
0100 0101
0.270
121
0111 1001
0.473
173
1010 1101
0.676
225
1110 0001
0.879
18
0001 0010
0.070
70
0100 0110
0.273
122
0111 1010
0.477
174
1010 1110
0.680
226
1110 0010
0.883
19
0001 0011
0.074
71
0100 0111
0.277
123
0111 1011
0.480
175
1010 1111
0.684
227
1110 0011
0.887
20
0001 0100
0.078
72
0100 1000
0.281
124
0111 1100
0.484
176
1011 0000
0.688
228
1110 0100
0.891
21
0001 0101
0.082
73
0100 1001
0.285
125
0111 1101
0.488
177
1011 0001
0.691
229
1110 0101
0.895
22
0001 0110
0.086
74
0100 1010
0.289
126
0111 1110
0.492
178
1011 0010
0.695
230
1110 0110
0.898
23
0001 0111
0.090
75
0100 1011
0.293
127
0111 1111
0.496
179
1011 0011
0.699
231
1110 0111
0.902
24
0001 1000
0.094
76
0100 1100
0.297
128
1000 0000
0.500
180
1011 0100
0.703
232
1110 1000
0.906
25
0001 1001
0.098
77
0100 1101
0.301
129
1000 0001
0.504
181
1011 0101
0.707
233
1110 1001
0.910
26
0001 1010
0.102
78
0100 1110
0.305
130
1000 0010
0.508
182
1011 0110
0.711
234
1110 1010
0.914
27
0001 1011
0.105
79
0100 1111
0.309
131
1000 0011
0.512
183
1011 0111
0.715
235
1110 1011
0.918
28
0001 1100
0.109
80
0101 0000
0.313
132
1000 0100
0.516
184
1011 1000
0.719
236
1110 1100
0.922
29
0001 1101
0.113
81
0101 0001
0.316
133
1000 0101
0.520
185
1011 1001
0.723
237
1110 1101
0.926
30
0001 1110
0.117
82
0101 0010
0.320
134
1000 0110
0.523
186
1011 1010
0.727
238
1110 1110
0.930
31
0001 1111
0.121
83
0101 0011
0.324
135
1000 0111
0.527
187
1011 1011
0.730
239
1110 1111
0.934
32
0010 0000
0.125
84
0101 0100
0.328
136
1000 1000
0.531
188
1011 1100
0.734
240
1111 0000
0.938
33
0010 0001
0.129
85
0101 0101
0.332
137
1000 1001
0.535
189
1011 1101
0.738
241
1111 0001
0.941
34
0010 0010
0.133
86
0101 0110
0.336
138
1000 1010
0.539
190
1011 1110
0.742
242
1111 0010
0.945
35
0010 0011
0.137
87
0101 0111
0.340
139
1000 1011
0.543
191
1011 1111
0.746
243
1111 0011
0.949
36
0010 0100
0.141
88
0101 1000
0.344
140
1000 1100
0.547
192
1100 0000
0.750
244
1111 0100
0.953
37
0010 0101
0.145
89
0101 1001
0.348
141
1000 1101
0.551
193
1100 0001
0.754
245
1111 0101
0.957
38
0010 0110
0.148
90
0101 1010
0.352
142
1000 1110
0.555
194
1100 0010
0.758
246
1111 0110
0.961
39
0010 0111
0.152
91
0101 1011
0.355
143
1000 1111
0.559
195
1100 0011
0.762
247
1111 0111
0.965
40
0010 1000
0.156
92
0101 1100
0.359
144
1001 0000
0.563
196
1100 0100
0.766
248
1111 1000
0.969
41
0010 1001
0.160
93
0101 1101
0.363
145
1001 0001
0.566
197
1100 0101
0.770
249
1111 1001
0.973
42
0010 1010
0.164
94
0101 1110
0.367
146
1001 0010
0.570
198
1100 0110
0.773
250
1111 1010
0.977
43
0010 1011
0.168
95
0101 1111
0.371
147
1001 0011
0.574
199
1100 0111
0.777
251
1111 1011
0.980
44
0010 1100
0.172
96
0110 0000
0.375
148
1001 0100
0.578
200
1100 1000
0.781
252
1111 1100
0.984
45
0010 1101
0.176
97
0110 0001
0.379
149
1001 0101
0.582
201
1100 1001
0.785
253
1111 1101
0.988
46
0010 1110
0.180
98
0110 0010
0.383
150
1001 0110
0.586
202
1100 1010
0.789
254
1111 1110
0.992
47
0010 1111
0.184
99
0110 0011
0.387
151
1001 0111
0.590
203
1100 1011
0.793
255
1111 1111
0.996
48
0011 0000
0.188
100
0110 0100
0.391
152
1001 1000
0.594
204
1100 1100
0.797
49
0011 0001
0.191
101
0110 0101
0.395
153
1001 1001
0.598
205
1100 1101
0.801
50
0011 0010
0.195
102
0110 0110
0.398
154
1001 1010
0.602
206
1100 1110
0.805
51
0011 0011
0.199
103
0110 0111
0.402
155
1001 1011
0.605
207
1100 1111
0.809
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Table 12. RGB Duty Cycle Control Settings
RGB_D4 RGB_D3 RGB_D2 RGB_D1 RGB_D0
82
DC(%)
FLASH_PER3
FLASH_PER2
FLASH_PER1
FLASH_PER0
0
0
0
0
0
0.00
0
0
0
0
1
0
0
0
0
1
3.23
0
0
0
1
1.5
0
0
0
1
0
6.45
0
0
1
0
2
0
0
0
1
1
9.68
0
0
1
1
2.5
0
0
1
0
0
12.90
0
1
0
0
3
0
0
1
0
1
16.13
0
1
0
1
3.5
0
0
1
1
0
19.35
0
1
1
0
4
0
0
1
1
1
22.58
0
1
1
1
4.5
0
1
0
0
0
25.80
1
0
0
0
5
0
1
0
0
1
29.03
1
0
0
1
5.5
0
1
0
1
0
32.25
1
0
1
0
6
0
1
0
1
1
35.48
1
0
1
1
6.5
0
1
1
0
0
38.70
1
1
0
0
7
0
1
1
0
1
41.93
1
1
0
1
7.5
0
1
1
1
0
45.15
1
1
1
0
8
0
1
1
1
1
48.38
1
1
1
1
Continuous
1
0
0
0
0
51.60
1
0
0
0
1
54.83
1
0
0
1
0
58.05
FLASH_ON2
FLASH_ON1
FLASH_ON0
ON_TIME (s)
1
0
0
1
1
61.23
0
0
0
0.1
1
0
1
0
0
64.50
0
0
1
0.15
1
0
1
0
1
67.73
0
1
0
0.2
1
0
1
1
0
70.95
0
1
1
0.25
1
0
1
1
1
74.18
1
0
0
0.3
1
1
0
0
0
77.40
1
0
1
0.4
1
1
0
0
1
80.63
1
1
0
0.5
1
1
0
1
0
83.85
1
1
1
0.6
1
1
0
1
1
87.08
1
1
1
0
0
90.30
1
1
1
0
1
93.53
1
1
1
1
0
96.75
1
1
1
1
1
99.98
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Table 13. PWM Frequency and Duty Cycle Settings
PWM FREQUENCY TABLE
PWM_D DUTY CYCLE
PWM_F2
PWM_F1
PWM_F0
F (Hz)
PWM2_D3
PWM2_D2
PWM2_D1
PWM2_D0
D_cycle (pu)
0
0
0
15600
0
0
0
0
0.0625
0
0
1
7800
0
0
0
1
0.125
0
1
0
4500
0
0
1
0
0.1875
0
1
1
3000
0
0
1
1
0.25
1
0
0
2000
0
1
0
0
0.3125
1
0
1
1500
0
1
0
1
0.375
1
1
0
1000
0
1
1
0
0.4375
1
1
1
500
0
1
1
1
0.5
1
0
0
0
0.5625
1
0
0
1
0.625
1
0
1
0
0.6875
1
0
1
1
0.75
1
1
0
0
0.8125
1
1
0
1
0.875
1
1
1
0
0.9375
1
1
1
1
1
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FUNCTIONALITY GUIDE – GENERAL PURPOSE INPUTS/OUTPUTS
GPIO3 FUNCTIONS
CONFIGURED AS OUTPUT
CONFIGURED AS INPUT
POWER-UP
DEFAULT
OUTPUT LEVEL
Io(max)
mA
A/D CONVERSION START TRIGGER
HI or LO at output set
via I2C
5
Falling or rising edge selected via I2C
Input, no mode
selected
CONFIGURED AS INPUT
POWER-UP
DEFAULT
GPIO2 FUNCTIONS
CONFIGURED AS OUTPUT
OUTPUT LEVEL
Io(max)
mA
HOST INTERRUPT
REQUEST
SM2 ENABLE
HI or LO at output set
via I2C
5
Set INT pin to LO via I2C
when GPIO2 pin edge is
detected. Rising or falling
edge detection selected via
I2C
GPIO2 level sets SM2 converter ON/OFF operation.
GPIO2 pin level (HI or LO) for ON operation
selected via I2C
Input, no mode
selected
The host interrupt request and SM2 enable GPIO2 functions are mutually exclusive,
and they should NOT be configured simultaneously
GPIO1 FUNCTIONS
CONFIGURED AS OUTPUT
CONFIGURED AS INPUT
OUTPUT LEVEL
Io(max)
mA
HOST INTERRUPT
REQUEST
SM1 ENABLE
SM1 AND SM2 STANDBY
CONTROL
HI or LO at output set
via I2C
5
Set INT pin to LO via I2C
when GPIO1 pin edge is
detected. Rising or falling
edge detection set via I2C
GPIO1 level sets SM1
converter ON/OFF
operation. GPIO2 pin
level (HI or LO) for ON
operation set via I2C
GPIO1 level sets SM2 and
SM1 converters in standby
mode. GPIO1 pin level (HI
or LO) for standby mode
set selected via I2C
POWER-UP
DEFAULT
Input, no mode
selected
The host interrupt request, SM1 enable and SM1/SM2 standby control GPIO1
functions are mutually exclusive, and they should NOT be configured
simultaneously.
TPS65800
GPIO1
CONFIGURATION MODES:
1-OUTPUT
2-SM1/SM2 STANDBY CONTROL INPUT
3-SM1 ON/OFF CONTROL INPUT
4-INTERRUPT REQUEST CONTROL INPUT
GENERATES INT PIN HI®LO TRANSITION
I2C
SETTINGS
GPIO
FUNCTION
GPIO
GPIO2
CONTROL
AND MODE
CONFIGURATION MODES:
1-OUTPUT
2-SM2 ON/OFF CONTROL
3-INTERRUPT REQUEST CONTROL INPUT
4-GENERATES INT PIN HI®LO TRANSITION
GPIO3
CONFIGURATION MODES:
1-OUTPUT
2-ADC TRIGGER CONTROL
3-LDC0 ENABLE
4-CHARGE VOLTAGE SELECTION
Figure 57. Required External Components, Recommended Values, External Connections
84
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General Purpose I/Os — GPIO 1, 2, 3
The TPS65800 integrates 3 general purpose open drain ports (GPIOs) that can be configured as selectable
inputs or outputs. When configured as outputs the output level can be set to LO or HI via I2C commands. When
the GPIOs are configured as inputs the action to be taken when a transition or HI/LO level is detected at the
GPIO pin is selectable via I2C.
When configured as inputs the GPIOs can be set in the following modes:
1. Interrupt request: In this mode of operation, a transition at the GPIO pin generates an interrupt request at
the interrupt controller. The GPIO interrupt request can be masked at the INT_MASK register. This
operation mode is available for GPIO’s 1 and 2.
2. SM1 and SM2 control: The GPIO’s can be used to turn the converters SM1 and SM2 ON/OFF, as well as
setting them in standby mode. This control mode is available for GPIO1 (SM1 on/off and SM1/SM2
standby) and GPIO2 (SM2 on/off control).
3. ADC trigger: GPIO3 can be configured as an external ADC trigger. The GPIO3 trigger configuration bit is
located at the ADC register ADC_DELAY.
GPIOs Input Level Configuration
When using I2C commands, the GPIO1 and GPIO2 pins can be configured as logic output signals or as
level-controlled inputs which enables (or disables) the switch mode converters SM1 and/or SM2. These pins
may also be configured as rising- or falling-edge-triggered inputs to externally control the generation of an
interrupt signal (INT), if desired.
The GPIO3 pin may be used as an external trigger source to start an A/D conversion cycle or as a logic output.
See Figure 58 for a description of the logic used for GPIO1 and GPIO2 inputs when configured for
edge-triggered interrupt generation. The signal from the GPIO pin input is double-latched before being sent to
the interrupt contoller logic. The inversion of the Q output from the first flip-flop must be HI to allow the output
latch to be cleared when a READ command occurs. On the initial edge of the GPIO signal, the Q output of the
flip-flop is set (HI). The INT line is asserted (LO) after the initial selected edge from the GPIO pin. On the next
falling (or rising) edge of the GPIO pin, the interrupt can again be cleared (which allows the INT pin to go back
high). The INT signal is cleared (set back HI) after an I2C READ operation is performed.
Thus, two successive edges of the GPIO signal, followed by an I2C READ command, are required to clear the
INT pin output. If no I2C READ commands occur, repeatedly applying edges to the GPIO pin does not toggle the
state of the INT pin output.
In addition to an I2C READ command after two GPIO edges, a UVLO event or reconfiguration of the GPIO pins
as outputs also de-asserts the INT signal.
2
I C INTACK READ
Command?
Multiplexer
S1
GPIO
Signal Pin
Equivalent circuit for internal
logic when configured as edge
interrupt with no masking
D Q
INT
D
INT
Q
CLR
S2
C
SET
ENB
HI = Rising Edge,
LO = Falling Edge
UVLO
GPIO Config = OUTPUT
Figure 58. GPIO 1 or GPIO2 Configured as an Interrupt Request Input
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Function Implementation: I2C Commands × GPIO Commands
Some of the GPIO SM1/SM2 control functions overlap I2C register control functions. Table 14 describes the
TPS65800 action when the GPIO’s command and I2C registers commands are not compatible with each other.
Table 14. GPIO Commands and I2C Registers Commands
86
SM1 AND SM2 ON/OFF I2C COMMAND
GPIO COMMAND
SM1 OR SM2 MODE SET
CONVERTER DISABLED
DON’T CARE
DISABLED
CONVERTER ENABLED
CONVERTER ENABLED
ENABLED
DON’T CARE
CONVERTER DISABLED
DISABLED
SM1 AND SM2 STANDBY I2C COMMAND
GPIO COMMAND
SM1 OR SM2 MODE SET
DO NOT SET STANDBY
DON’T CARE
NORMAL
SET STANDBY
SET STANDBY
STANDBY
DON’T CARE
DO NOT SET STANDBY
NORMAL
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GPIO Configuration Table
Table 15 describes the I2C register settings required to program the available GPIO modes.
Table 15. Recommended GPIO Configuration Procedure
GPIO MODE
I2C
I2C REGISTER BIT SETTING
ADDITIONAL DETAILS
GPIO3I/O=HI AND GPIO3OUT=HI
GPIO3 PIN SET TO HIGH IMPEDANCE
MODE
GPIO3I/O=HI AND GPIO3OUT=LO
V(GPIO3) = VOL
GPIO3I/O=LO AND ADC_TRG_GPIO3=HI AND
EDGE_GPIO3=HI
GPIO3 pin rising edge triggers ADC
conversion
GPIO3I/O=LO AND ADC_TRG_GPIO3=HI AND
EDGE_GPIO3=LO
GPIO3 pin falling edge triggers ADC
conversion
GPIO2I/O=HI AND GPIO2OUT=HI
GPIO2 PIN SET TO HIGH IMPEDANCE
MODE
GPIO2I/O=HI AND GPIO2OUT=LO
V(GPIO2) = VOL
GPIO2I/O=LO AND GPIO2INT=HI AND
GPIO2LVL=HI AND GPIO2SM2=LO
INT pin HI→LO→HI at V(GPIO2) falling
edge
GPIO2I/O=LO AND GPIO2INT=HI AND
GPIO2LVL=HI AND GPIO2SM2=LO
INT pin HI→LO→HI at V(GPIO2) rising
edge
GPIO2I/O=LO AND GPIO2INT=LO AND
GPIO2LVL=HI AND GPIO2SM2=HI
SM2 converter ON at V(GPIO2) = HI
GPIO2I/O=LO AND GPIO2INT=LO AND
GPIO2LVL=LO AND GPIO2SM2=HI
SM2 converter ON at V(GPIO2) = LO
GPIO1I/O=HI AND GPIO1OUT=HI
GPIO1 PIN SET TO HIGH IMPEDANCE
MODE
GPIO1I/O=HI AND GPIO1OUT=LO
V(GPIO1) = VOL
GPIO1I/O=LO AND GPIO1INT=HI AND
GPIO1LVL=HI AND GPIO1SM1=LO AND
GPIO1SMSBY=LO
INT pin HI→LO→HI at V(GPIO1) falling
edge
GPIO1I/O=LO AND GPIO1INT=HI AND
GPIO1LVL=LO AND GPIO1SM1=LO AND
GPIO1SMSBY=LO
INT pin HI→LO→HI at V(GPIO1) rising
edge
GPIO1I/O=LO AND GPIO1INT=LO AND
GPIO1LVL=HI AND GPIO1SM1=HI AND
GPIO1SMSBY=LO
SM1 converter ON at V(GPIO1) = HI
GPIO1I/O=LO AND GPIO1INT=LO AND
GPIO1LVL=LO AND GPIO1SM1=HI AND
GPIO1SMSBY=LO
SM1 converter ON at V(GPIO1) = LO
GPIO1I/O=LO AND GPIO1INT=LO AND
GPIO1LVL=HI AND GPIO1SM1=LO AND
GPIO1SMSBY=HI
SM1/SM2 converter standby set at
V(GPIO1) = HI
GPIO1I/O=LO AND GPIO1INT=LO AND
GPIO1LVL=LO AND GPIO1SM1=LO AND
GPIO1SMSBY=HI
SM1/SM2 converter standby set at
V(GPIO1) = LO
REGISTERS
GPIO3 = OUTPUT
GPIO3
GPIO3 =INPUT
ADC CONVERSION
START TRIGGER
GPIO3 AND
ADC_DELAY
GPIO2 = OUTPUT
GPIO12
GPIO2=INPUT,
HOST INTERRUPT
REQUEST
GPIO12 AND
GPIO3
GPIO2=INPUT,
SM2 ENABLE
GPIO12 AND
GPIO3
GPIO1 = OUTPUT
GPIO12
GPIO1=INPUT,
HOST INTERRUPT
REQUEST
GPIO12 AND
GPIO3
GPIO1=INPUT,
SM1 ENABLE
GPIO1=INPUT,
SM1/SM2 STANDBY
CONTROL
GPIO12 AND
GPIO3
GPIO12 AND
GPIO3
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GPIOs — I2C Registers
The I2C registers that control GPIO-related functions are shown below. The HEX address for each register is
shown by the register name, together with the R or W functionality for the register bits. Shaded values indicate
default initial power-up values.
B7
B6
B5
B4
B3
B2
B1
B0
GPIO12, ADDRESS=1B, ALL BITS R/W
Bit Name
GPIO2I/O
GPIO1I/O
GPIO2OUT
GPIO1OUT
GPIO2LVL
GPIO1LVL
GPIO1SMSBY
GPIO1SM1
Function
GPIO2 MODE
GPIO1 MODE
SET GPIO2
LEVEL
(OUTPUT
ONLY)
SET GPIO1
LEVEL
(OUTPUT
ONLY)
GPIO2 EDGE
AND LEVEL
DETECTION
GPIO1 EDGE
AND LEVEL
DETECTION
GPIO 1
CONTROLS
SM1 AND SM2
STANDBY
ON/OFF
GPIO1
CONTROLS
SM1 ON/OFF
When 0
INPUT
INPUT
LOW
LOW
RISING EDGE,
LO LEVEL
RISING EDGE,
LO LEVEL
DISABLED
DISABLED
When 1
OUTPUT
OUTPUT
HIGH
HIGH
FALLING
EDGE, HI
LEVEL
FALLING
EDGE, HI
LEVEL
ENABLED
ENABLED
GPIO3, ADDRESS=1C, ALL BITS R/W
Bit Name
GPIO3I/O
GPIO3OUT
LDO0_EN
CHG_VOLT
NOT USED
GPIO2 INT
GPIO1 INT
GPIO2SM2
Function
GPIO3 MODE
SET GPIO3
LEVEL
(OUTPUT
ONLY)
LDO0 ON/OFF
CONTROL
CHARGE
VOLTAGE
SAFETY BIT
NOT USED
GPIO2
TRIGGERS
INT:HI→LO
GPIO1
TRIGGERS
INT:HI→LO
SM2 ON/OFF
CONTROL
When 0
INPUT
LOW
OFF
4.20 V
NOT USED
DISABLED
DISABLED
DISABLED
When 1
OUTPUT
HIGH
ON
4.36 V
NOT USED
ENABLED
ENABLED
ENABLED
88
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APPLICATION INFORMATION
INDUCTOR AND CAPACITOR SELECTION — CONVERTERS SM1 AND SM2
SM1 and SM2 are designed with internal voltage mode compensation and the stabilization is based on choosing
an LC filter that has a corner frequency around 27 kHz. It is not recommended to use LC values that would be
outside the range of 13 kHz to 40 kHz.
Equation 9 calculates the corner frequency of the output LC filter. The standard recommended LC values are 3.3
µH and 10 µF.
1
F+
+ 27.7 kHz (a) for L + 3.3 mH and C + 10 mF
2p ǸLC
(9)
The inductor value, along with the input voltage VIN, output voltage VOUT and switching frequency f define the
ripple current. Typically the ripple current target is 30% of the full load current. At light loads it is desirable for
ripple current to be less then 150% of the light load current.
The inductor should be chosen with a rating to handle the peak ripple current., if an inductor’s current gets
higher than its rated saturation level (DCR), the inductance starts to fall off, and the inductor’s ripple current
increases exponentially. The DCR of the inductor plays an important role in efficiency and size of the inductor.
Larger diameter wire has less DCR but may increase the size of the inductor
Equation 10 calculates the target inductor value. If an inductor value has already been chosen, Equation 11,
calculates the inductor’s ripple current under static operating conditions. The ripple amplitude can be calculated
during the on time (positive ramp) or during the off time (negative ramp). It is easiest to calculate the ripple using
the off time, because the inductor’s voltage is the output voltage.
V OUT
I target +
0.3 I OUT_MAX
V
DI L + L
L
V
Dt + OUT
L
ǒ
1*
Ǔ
VOUT
VIN_MAX
f
ǒ
1*
(10)
Ǔ
VOUT
VIN
f
(11)
Equation 12 calculates the peak current due to the output load and ripple current
DI
I Lmax + I OUTmax ) L
2
(12)
For a faster transient response, a lower inductor and higher capacitance allows the output current to ramp faster,
while the addition capacitance holds up the output longer (a 2.2-µH inductor in combination with a 22-µF output
capacitor are recommended).
The highest inductor current occurs at the maximum input voltage. The peak inductor current during a transient
may be higher than the steady state peak current and should be considered when choosing an inductor.
Monitoring the inductor current for non-saturation operation during a transient of 1.2 × I_loadmax at Vin_max
ensures adequate saturation margin.
Table 16. Inductors for Typical Operation Conditions
DEVICE
INDUCTOR VALUE
TYPE
COMPONENT SUPPLIER
DCDC3 converter
3.3 µH
CDRH2D14NP-3R3
Sumida
3.3 µH
PDS3010-332
Coilcraft
3.3 µH
VLF4012AT-3R3M1R3
TDK
2.2 µH
VLF4012AT-2R2M1R5
TDK
2.2 µH
NR3015T2R2
Taoup-Uidem
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APPLICATION INFORMATION (continued)
Table 16. Inductors for Typical Operation Conditions (continued)
DEVICE
INDUCTOR VALUE
TYPE
COMPONENT SUPPLIER
DCDC2 converter
3.3 µH
CDRH2D18/HPNP-3R3
Sumida
3.3 µH
VLF4012AT-3R3M1R3
TDK
DCDC1 converter
2.2 µH
VLCF4020-2R2
TDK
3.3 µH
CDRH3D14/HPNP-3R2
Sumida
3.3 µH
CDRH4D28C-3R2
Sumida
3.3 µH
MSS5131-332
Coilcraft
2.2 µH
VLCF4020-2R2
TDK
OUTPUT CAPACITOR SELECTION, SM1, SM2 CONVERTERS
The advanced fast response voltage mode control scheme of the SM1, SM2 converters implemented in the
TPS65020 allow the use of small ceramic capacitors with a typical value of 10 µF for a 3.3-µH inductor, without
having large output voltage under and overshoots during heavy load transients.
Ceramic capacitors having low ESR values have low output voltage ripple, and recommended values and
manufacturers are listed in Table 1. Often, due to the low ESR, the ripple current rating of the ceramic capacitor
is adequate to meet the inductor’s currents requirements.
The RMS ripple current is calculated as:
V
1 * OUT
VIN
1
I RMSCout +
Ǹ3
2 L f
(13)
At nominal load current, the inductive converters operate in PWM mode. The overall output voltage ripple is the
sum of the voltage spike caused by the output capacitor ESR plus the voltage ripple caused by charging and
discharging the output capacitor: The output voltage ripple is maximum at the highest input voltage Vin.
V
1 * OUT
VIN
1
V RMSCout +
) ESR
L f
8 Cout f
(14)
ǒ
Ǔ
At light load currents, the converters operate in PFM and the output voltage ripple is dependent on the output
capacitor value. The output voltage ripple is set by the internal PFM output voltage comparator delay and the
external capacitor. The typical output voltage ripple is less than 1% of the nominal output voltage.
Table 17. Input/Output Capacitors for Typical Operation Conditions
90
CAPACITOR VALUE
CASE SIZE
COMPONENT SUPPLIER
COMMENTS
22 µF
22 µF
1260
TDK C3216X5R0J226M
Ceramic
1260
Taiyo Yuden JMK316BJ226ML
Ceramic
10 µF
0805
Taiyo Yuden JMK212BJ106M
Ceramic
10 µF
0805
TDK C2012X5R0J106M
Ceramic
22 µF
0805
TDK C2012X5R0J226MT
Ceramic
22 µF
0805
Taiyo Yuden JMK212BJ226MG
Ceramic
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INPUT CAPACITOR SELECTION, SM1, SM2 CONVERTERS
Buck converters have a pulsating input current that can generate high input voltage spikes at VIN. A low ESR
input capacitor is required to filter the input voltage, minimizing the interference with other circuits connected to
the same power supply rail. Each dc-dc converter requires a 10-µF ceramic input capacitor on its input pin.
OUTPUT VOLTAGE SELECTION, SM1, SM2 CONVERTERS
Typically the output voltage is programmed by the I2C. An external divider can be added to raise the output
voltage, if the available I2C values do not meet the application requirements. Care must be taken with this
special option, because this external divider (gain factor) would apply to any selected I2C output voltage value
for this converter.
Equation 16 calculates R1, Let R2 = 20 kΩ:
R1 +
ƪ
ƫ
V SMxOUT
* 1 R2
V FB
(16)
Where VFB is the I2C selected voltage, is the desired output voltage and R1/R2 is the feedback divider.
DESIGN EXAMPLES
SM1, SM2 CONVERTER DESIGN EXAMPLE
Design Conditions and Parametrs for SM1 or SM2:
Vin_SM1/2: 4.6V typical (May be less if input source is limited).
Vout_SM1/2: 1.24 V
Iout_max: 0.6 A
fsw = 1500 kHz
fc = 25 kHz
V OUT
L target +
0.3 I OUT_MAX
C+
L[2
1
p
fc] 2
ƪ
1*
ƫ
VOUT
VIN_MAX
fsw
+ 3.35 mH, 3.3 mH is a good target.
(17)
+ 10.5 mF 10 mF is a good target.
(18)
CHARGER DESIGN EXAMPLE
Design Conditions and Parameters for Charger:
Vout: 4.6 V; (OUT pin is input to charger)
Fast-charge current, IPGM: 1 A
DPPM-OUT threshold: 4.3 V; (charging current reduces when OUT falls to this level)
Safety timer: 5 h
Battery short circuit delay, tDELAY: 47 µs; (Delays BAT short circuit during hot plug of battery)
TS temperature range: disabled
KSET=400; VSET=2.5 V; KDPPM = 1.15; IDPPM = 100 µA; KTMR=0.36 s/Ω
Program Fast-Charge Current Level:
K
VSET
R ISET + SET
+ 1 kW
I PGM
(19)
Program DPPM_OUT Voltage Level (Level at Which Charging Current Reduces)
V DPPM_OUT
R DPPM +
+ 3.74 kW
KDPPM I DPPM
(20)
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Program BAT Short-Circuit Delay (Used for Inserting Battery)
C DPPM + t DELAY I DPPM + 4.7 Nf
(21)
Program 5-Hour Safety Timer
t
3600 secńhr
R TMR + SAFETY*HR
+ 50 kW
K TMR
(22)
Disable/Program TS
RTS = 49.9 kΩ– fixed resistor to disable TS input.
VTS = ITS× RTS = 20 µA × 49.9 kΩ = 0.998 V
The TS pin has a 20-µA current source output that biases the resistor or thermistor. If VTS is within the 0.5- to
2.5-V window, normal operation is allowed. If a 503AT thermistor is used, the typical range is 4°C to 41°C.
92
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PACKAGE OPTION ADDENDUM
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5-Feb-2007
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
TPS65800RTQR
ACTIVE
QFN
RTQ
56
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
TPS65800RTQRG4
ACTIVE
QFN
RTQ
56
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
TPS65800RTQT
ACTIVE
QFN
RTQ
56
250
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
TPS65800RTQTG4
ACTIVE
QFN
RTQ
56
250
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-3-260C-168 HR
Lead/Ball Finish
MSL Peak Temp (3)
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Oct-2007
TAPE AND REEL BOX INFORMATION
Device
Package Pins
Site
Reel
Diameter
(mm)
Reel
Width
(mm)
A0 (mm)
B0 (mm)
K0 (mm)
P1
(mm)
W
Pin1
(mm) Quadrant
TPS65800RTQR
RTQ
56
SITE 41
330
16
8.3
8.3
2.25
12
16
Q2
TPS65800RTQT
RTQ
56
SITE 41
180
16
8.3
8.3
2.25
12
16
Q2
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
5-Oct-2007
Device
Package
Pins
Site
Length (mm)
Width (mm)
TPS65800RTQR
RTQ
56
SITE 41
346.0
346.0
33.0
TPS65800RTQT
RTQ
56
SITE 41
190.0
212.7
31.75
Pack Materials-Page 2
Height (mm)
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