ACTIVE-SEMI ACT4911QW301-T Power loss protection with 6a efuse Datasheet

ACT4911QW
Rev 1.0, 15-Sept-2017
Power Loss Protection with 6A eFuse
BENEFITS and FEATURES
GENERAL DESCRIPTION
Wide 2.7-to-8V Operating Input Range
10V Max Input Blocking Voltage
Adjustable Bus Voltage Start-Up Slew Rate for Inrush Current Control
Configurable Input power Failure Level
Programmable up to 10A Input Current Limit
Programmable 5V to 36V Boost Storage Voltage
36V@6A Synchronous Buck Supports 100% Duty
Cycle
Programmable up to 1.13MHz Buck Operating Frequency for Small Inductor Size
Undetectable Transition from Input Supply to Capacitor Bank Power
Compatible with Different Types of Storage Caps:
Super Caps, Electrolytic, Tantalum, POSCAP
etc.
ADC Monitoring of Critical Signals
Autonomous Health Monitoring for Detection of
Earlier Storage Capacitor Failures
Configurable Interrupts to Inform Host for any
Faults/Status Change
eFuse, Boost, and Buck UV/OV/OC Protection
Thermal Alert and Protection
Thermal Enhanced FCQFN 5x5-28 package
The ACT4911 device is a highly integrated power loss
protection IC. It provides backup storage power in the
event of an input power failure. A built-in boost
converter provides high voltage energy storage to
minimize storage capacitor size requirements. The
built-in buck converter regulates the storage voltage to
a fixed output voltage. It contains internal, back-toback eFuse FETs to provide bi-directional input to
output isolation. The IC also provides hot swap and
inrush current control.
The ACT4911 is very flexible and can easily be
configured with I2C and external components. It
features programmable storage capacitor voltage to
optimize the storage capacitor sizing and system run
time. The internal ADC and health monitoring provide
an extra layer of protection and improve system
reliability and early capacitor failure notification. It
automatically checks the storage capacitor health and
notifies the user when the energy in the storage caps
is not sufficient for backup power. The ADC also
measures the input voltage, output voltage, storage
voltage, eFuse current, and die temperature. The builtin synchronous buck converter maximizes energy
transfer from the storage caps to the system.
ACT4911 provides an I2C bus interface to allow MCU
control and monitoring. There are supervisor monitors
for the input voltage, output voltage, and storage
voltage. It is available with the thermal enhanced QFN
5x5 28 pins package.
APPLICATIONS
•
•
•
•
Solid State Drives
Industrial Applications
Backup Power
Hot Plug Devices
eFuse 17mΩ
Inrush Controller
Input 2.7V‐8V
Blocking up to 10V
Caps
5V-36V
5V-36V
2.7V‐8V
Health Monitor/
ADC
36V Buck/Boost
Controller
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
40mΩ
FET
PMU
System
Core/Flash
25mΩ
FET
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
1
ACT4911QW
Rev 1.0, 15-Sept-2017
FUNCTIONAL BLOCK DIAGRAM
VIN
VOUT
QBLOCK1
STR
QBLOCK2
Health
Monitor
ISET
HSB
Block FET
Controller
QHS
SS
SW
0.64V
EN
QLS_BOOST
QLS_BUCK
PGND
EN_OV_REF
SCL
Main
Controller
Buck/Boost
Controller
FB
SDA
COMP
nIRQ
BSET
VREF
PLI
REF
VSS
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
2
ACT4911QW
Rev 1.0, 15-Sept-2017
ORDERING INFORMATION
PART NUMBER
Input
Voltage
Storage
Voltage
Fsw
PLI Function
7 Bit I2C
Address
PACKAGE
ACT4911QW301-T
3.3V
28V
900kHz
PLI & VOUT OK
0x3Ah
FCQFN5x5-28
ACT49 11QWxxx-T
Product Number
Package Code
Pin Count
CMI Option
Tape and Reel
Note 1: Standard product options are identified in this table. Contact factory for custom options, minimum order quantity required.
Note 2: All Active-Semi components are RoHS Compliant and with Pb-free plating unless specified differently. The term Pb-free means semiconductor
products that are in compliance with current RoHS (Restriction of Hazardous Substances) standards.
Note 3: Package Code designator “Q” represents QFN
Note 4: Pin Count designator “W” represents 28 pins
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
3
ACT4911QW
Rev 1.0, 15-Sept-2017
PGND
SW
STR
VOUT
VOUT
VOUT
VIN
PIN CONFIGURATION
28
27
26
25
24
23
22
VIN
PGND
3
19
VIN
BSET
4
18
VIN
REF
5
17
EN
COMP
6
16
SS
FB
7
15
ISET
8
9
10
11
12
13
14
nIRQ
20
VOUT
2
VOUT
PLI
VOUT
VIN
SDA
21
SCL
1
VSS
HSB
Figure 1: Pin Configuration – Top View – QFN5x5-28
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
4
ACT4911QW
Rev 1.0, 15-Sept-2017
PIN DESCRIPTIONS
PIN
NAME
DESCRIPTION
1
HSB
High Side Bias, Boot-strap pin. This provides power to the internal high-side
MOSFET gate driver circuitry. Connect a 47nF capacitor from HSB pin to SW pin
2
PLI
Power Loss Indicator Open-Drain Output. PLI goes low to indicate loss of input
power. Can also be configured as a storage voltage monitor or an output voltage
monitor. PLI is referenced to VSS.
3, 28
PGND
Power Ground. Connect to large ground plane on PCB
4
BSET
Sets the storage capacitor voltage. Place a resistor from BSET to VSS to set the
desired voltage.
5
REF
6
COMP
7
FB
8
VSS
Analog Ground. Kelvin connect VSS to the PGND plane.
9
SCL
I2C Clock Input. Needs an external pull up resistor.
10
SDA
I2C Data Input and Output. Needs an external pull up resistor.
11,12,13,2
3, 24, 25
VOUT
Output for by-pass mode, in-rush, and eFuse functionality. Connect VOUT to the
system load.
14
nIRQ
Interrupt Open-Drain Output. nIRQ goes low to indicate a fault condition. nIRQ is
referenced to VSS.
15
ISET
Input and Output Current Limit pin. ISET can also indicate the load current through
the eFuse. Connect a resistor from ISET to VSS to set the current limit.
16
SS
Soft Start Input. Place a capacitor from SS to VSS to control the eFuse startup
voltage slew rate.
17
EN
Enable Input. A dual comparator on EN measures the input voltage to determine if
it is under, voltage, over voltage, or within normal operating limits. Connect a
resistive voltage divider between VIN, EN, and VSS to set the EN_UV and EN_UV
thresholds. The EN_UV threshold is 0.64V. The EN_OV threshold is typically
0.92V, but can be modified by the IC’s CMI.
18,19, 20,
21, 22
VIN
Power Supply Input. Input to the eFuse. Connect a 0.1µF capacitor between VIN
and PGND as close to the IC as possible.
26
STR
Storage Capacitor Input. Connect the storage capacitors to STR. STR requires a
minimum capacitor of 100µF to PGND.
27
SW
Switching Pin. This is the boost converter switch node and the buck converter
switch node. Connect the inductor to SW.
Internal Bias Voltage Output. Connect a 1µF capacitor between REF and VSS.
Compensation input pin for the buck converter.
Output Voltage Feedback. Kelvin connect FB to the output capacitor.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
5
ACT4911QW
Rev 1.0, 15-Sept-2017
ABSOLUTE MAXIMUM RATINGS
PARAMETER
VALUE
UNIT
FB, SS, ISET, REF, SDA, SCL, EN, BSET, nIRQ to VSS
-0.3 to 6
V
VIN, VOUT to PGND (ACT4911)
-0.3 to 12
V
HSB to SW
-0.3 to 6
V
SW to PGND
-0.3 to STR+ 0.3
V
PLI to VSS
-0.3 to 24
V
STR to PGND
-0.3 to 40
V
VSS to PGND
-0.3 to + 0.3
V
ESD Rating (human body model), all pins
2
kV
Junction to Ambient Thermal Resistance, dependent on board layout
16.8
°C /W
Operating Ambient Temperature Range (TA)
-40 to 105
°C
Operating Junction Temperature (TJ), (note 1)
-40 to 125
°C
Storage Temperature
-40 to 150
°C
Lead Temperature (Soldering 10s)
300
°C
Note1: Do not exceed these limits to prevent damage to the device. Exposure to absolute maximum rating conditions for long periods may affect
device reliability.
Note2: Measured on Active-Semi Evaluation Kit
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
6
ACT4911QW
Rev 1.0, 15-Sept-2017
SYSTEM CHARACTERISTICS
(VIN = 5V, TA = 25°C, unless otherwise specified)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
8
V
Input Supply
Input Supply Voltage Range
VIN
2.7
Input Supply Power On Reset (Internal)
VIN Rising
2.53
V
Input Supply Power On Reset
Hysteresis (Internal POR)
VIN Falling
90
mV
9.5
V
Input Supply Over Voltage Lock Out
(OVLO)
Input Under Voltage Lock Out (UVLO)
VIN Rising (Boost/eFuse Enabled)
Input UVLO Hysteresis
VIN Falling
Input Operation Current
Input Current (Shutdown)
2.65
2.7
50
V
mV
eFuse Enabled and Soft start completed
Buck/Storage Regulator Disabled
ADC Disabled
Storage Health Check Disabled
3
mA
eFuse Enabled and Soft start completed
Buck/Storage Regulator Disabled
ADC Enabled
Storage Health Check Disabled
5.5
mA
VEN=0V
470
µA
Sets nIRQ
120
°C
Thermal Shutdown – Disables buck and
boost
145
°C
Thermal Shutdown – Disables eFuse
155
°C
Thermal Comparators Hysteresis
15
°C
Thermal
Thermal Warning
SET Thresholds
BSET Current Source
BSET = 1.0V (25°C)
19.6
BSET Current Source Temperature
Coefficient
BSET = 1.0V (25°C – 125°C)
20
20.4
µA
0.011
%/°C
STR Thresholds
Input Under Voltage Lock Out
(STR_UVLO)
STR Falling
3.6
V
Input Under Voltage Lock Out
(STR_UVLO)
STR Rising
4.0
V
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
7
ACT4911QW
Rev 1.0, 15-Sept-2017
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
5
V
100
Ω
0.65
V
Open Drain Outputs
Switch Maximum Voltage Range
(nIRQ,PG_STR, SDA)
Switch resistance (nIRQ,PG_STR, SDA)
0
Sinking Current 500µA
Enable Thresholds
Under Voltage Reference
UV REF after POR release (-40°C ~ 125°C)
Overvoltage Reference Programmable
Range
OV REF after POR release
EN Deglitch Time
EN UV Rising or OV Falling (0ms turn-on delay)
Hysteresis for Reference
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
0.63
0.64
0.92
V
1
ms
17
mV
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
8
ACT4911QW
Rev 1.0, 15-Sept-2017
INTERNAL BUCK REGULATOR
(VIN = 5V, TA = 25°C, unless otherwise specified)
CONDITIONS
PARAMETER
Operating Input Voltage Range
MIN
TYP
4.2
Typical Output Voltage
MAX
UNIT
36
V
3.3
Programmable Output Voltage Range
Using external resistor divider
Standby Supply Current
VOUT = 103%, Regulator Enabled, No Load, not switching
1.8
Feedback Voltage
V
8
V
500
µA
1.2
V
Output Voltage Accuracy
VOUT = 3.3V, IOUT = 2A (PWM mode)
-1%
VNOM
1%
V
Output Voltage Accuracy
VOUT =3.3V, IOUT = 1mA (PFM mode)
-1%
VNOM
1%
V
Line Regulation
VOUT = 3.3V, VIN = 5.5V to 12V, PWM Regulation
0.02
%/V
Load Regulation
VOUT = 3.3V, PWM Regulation
0.04
%/A
Power Good Threshold
VOUT Rising
Power Good Hysteresis
VOUT Falling
Overvoltage Fault Threshold
VOUT Rising
Overvoltage Fault Hysteresis
VOUT Falling
90.5
95.5
3
107
110
320
BK_CLIM = 00
BK_CLIM = 01
BK_CLIM = 10
BK_CLIM = 11
%VNOM
%VNOM
113
2
Programmable Switching Frequency
Range
Current Limit, Cycle-by-Cycle
93
%VNOM
%VNOM
1130
5.0
6.0
7.0
9.0
kHz
A
At default BK_CLIM
-10%
+10%
At other set points
-15%
+15%
Current Limit, Shutdown
Above BK_CLIM
+15%
High Side On-Resistance
ISW = -3A, VSTR = 12V
45
mΩ
Low Side On-Resistance
ISW = 3A, VSTR = 12V
28
mΩ
SW Leakage Current
VSTR = 12V, VSW = 0 or 5.5V
Current Limit, Cycle-by-Cycle Tolerance
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
+22.5%
+30%
1
µA
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
9
ACT4911QW
Rev 1.0, 15-Sept-2017
INTERNAL EFUSE
(VIN = 5V, TA = 25°C, unless otherwise specified)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
8
V
Normal Mode
Operating Voltage Range
2.7
ISW = -2A, VIN= 3.3V and 5V TJ = 25°C
17
mΩ
24.5
mΩ
eFuse On-Resistance
ISW = -2A, VIN= 3.3V and 5V, TJ = 100°C
Programmable eFuse Current Limit
Range
VIN = 5V Configured using ISET pin, Triggers nIRQ Pin
1
10
A
VIN = 3.3V, Configured using ISET pin, Triggers nIRQ
Pin
1
7
A
Internal Path Current Regulation Accuracy VISET
ISET Monitor Current Ratio
1
ISET current divided by eFuse current
V
1/50,000
eFuse Overcurrent Detection Deglitch
10
µs
eFuse Overcurrent Current Shutdown
11
A
100
ms
Current Limit Restart Time
eFuse Soft start
CSS = 10nF
5.94
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
6.6
7.26
mV/us
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
10
ACT4911QW
Rev 1.0, 15-Sept-2017
STORAGE BOOST REGULATOR
(VIN = 5V, TA = 25°C, unless otherwise specified)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Storage Boost Converter
Operating Voltage Range
2.7
36
V
Programmable Output Voltage Range
5.0
36
V
Peak switching Current
BST _CLIM = 00
BST _CLIM = 01
BST _CLIM = 10
BST _CLIM = 11
250
650
950
1500
Standby Supply Current
VSTR = 103%, Regulator Enabled, not switching
Output Voltage Accuracy
VSTRr = 28V, IOUT = 15mA (continuous PWM mode)
Power Good Threshold
VSTR Rising
Power Good Hysteresis
VSTR Falling
Overvoltage Fault Threshold
Overvoltage Fault Hysteresis
25
40
µA
VNOM
3%
V
95
%VNOM
5
%VNOM
VSTR Rising
110
%VNOM
VSTR Falling
3
%VNOM
50
ns
300
mΩ
2
Minimum On-Time
Low Side FET On-Resistance
-3%
mA
ISW = 325mA
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
11
ACT4911QW
Rev 1.0, 15-Sept-2017
HEALTH MONITOR
(VIN = 5V, TA = 25°C, unless otherwise specified)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
40
V
11
mA
Health Monitor
Operating Voltage Range
4.2
Sink Current Source
9
Programmable Health Monitor Current
Sink Timer Range
2
1280
ms
95
98
%
3
20
V
5
mA
Programmable Storage Voltage Threshold
Range
Configurable 0.2% steps
10
ADC Monitoring
Operating Voltage Range
Supply Current
Enabled
2
Total Error
5V scale and 8 bit range
0.5
LSB
Conversion Time
Total time for all channels
100
ms
2.5
V
Full Scale Input Range
-2.5
Input Resistance
10
kΩ
Input Capacitance
5
pF
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
12
ACT4911QW
Rev 1.0, 15-Sept-2017
I2C INTERFACE ELECTRICAL CHARACTERISTICS
(VIN = 5V, TA = 25°C, unless otherwise specified.)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
SCL, SDA Input Low
VIO = 1.8V
0.6
V
SCL, SDA Input High
VIO = 1.8V
SDA Leakage Current
SDA=5V
1
µA
SDA Output Low
IOL = 5mA
0.35
V
1000
kHz
1.2
SCL Clock Frequency, fSCL
V
0
SCL Low Period, tLOW
0.5
µs
SCL High Period, tHIGH
0.26
µs
50
ns
0
ns
SDA Data Setup Time, tSU
SDA Data Hold Time, tHD
(Note1)
Start Setup Time, tST
For Start Condition
260
ns
Stop Setup Time, tSP
For Stop Condition
260
ns
Capacitance on SCL or SDA Pin
10
pF
SDA Rise Time SDA, Tr
Device requirement
120
ns
SDA Fall Time SDA, Tf
Device requirement
120
ns
50
ns
Pulse Width of spikes must be suppressed
on SCL and SDA
0
Note1: Comply with I2C timings for 1MHz operation - “Fast Mode Plus”.
Note2: No internal timeout for I2C operations, however, I2C communication state machine will be reset when entering UV/POR State.
Note3: This is an I2C system specification only. Rise and fall time of SCL & SDA not controlled by the device.
Note4: Device Address is factory configurable to 7’h1A, 7’h3A, 7’h5A.
tSCL
SCL
tST
tHD
tSU
tSP
SDA
Start
condition
Stop
condition
Figure 2: I2C Data Transfer
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
13
ACT4911QW
Rev 1.0, 15-Sept-2017
FUNCTIONAL DESCRIPTION
General
I2C Serial Interface
ACT4911 provides protection, control, and supplemental storage for power failure prevention systems.
This functionality goes by many names: Power Loss
Protection (PLP), Power Loss Imminent (PLI) and
Power Failure Protection (PFP). It provides a system
with additional run time after a power failure to all the
system to save critical data before shutting down. Typical applications include solid state disk drives (SSD)
and servers. In normal operation when input power is
good, the IC connects the input to the output through
the eFuse. This powers the system load from the system input power. If an input voltage fault occurs, the IC
disconnects the input from the output and enters supplement mode, where output power comes from the
high voltage storage capacitor power. The internal buck
converter efficiently converts the storage voltage down
to the regulated output voltage. All startup, storage capacitor charging, and switching between normal and
supplement mode operation is autonomous and does
not require user intervention.
To ensure compatibility with a wide range of systems,
the ACT4911 uses standard I2C commands. The
ACT4911 operates as a slave device, and can be factory configured to one of three 7-bit slave addresses.
The 7-bit slave address is followed by an eighth bit,
which indicates whether the transaction is a read-operation or a write-operation. Refer to each specific CMI for
the IC’s slave address
7-Bit Slave Address
0x1Ah
0x3Ah
0x5Ah
001 1010b
011 1010b
101 1010b
8-Bit Write
Address
0x34h
0x74h
0xB4h
8-Bit Read
Address
0x35h
0x75h
0xB5h
The I2C packet processing state machine does not have
a timeout function, however, any time the I2C state machine receives a start bit command, it immediately resets the packet processing, even if it is in the middle of
a valid packet. The I2C functionality is operational in all
states except RESET.
During start up, the ACT4911 limits the output voltage
dV/dt to minimize system level inrush currents. After
softstart is complete, the IC charges the storage capacitors with the internal boost converter. The IC automatically recharges the storage capacitors as needed. The
IC contains extensive protection circuitry to protect
against input voltage overvoltage and undervoltage,
output voltage overload and short circuit, degraded storage capacitors, and thermal overload.
I2C commands are communicated using the SCL and
SDA pins. SCL is the I2C serial clock input. SDA is the
data input and output. SDA is open drain and must have
a pull-up resistor. Signals on these pins must meet
timing requirements in the Electrical Characteristics
Table.
I2C Registers
The IC communicates with the host processor via I2C
and GPIOs. The nIRQ pin indicates general faults which
can be read by the host processor via I2C. A dedicated
power failure pin, PLI, automatically and immediately
goes low to indicate a power loss condition. This gives
the system advanced warning to complete all active
tasks and shutdown. See the Pin Function section for
additional PLI pin functionality.
The ACT4911 contains an array of internal registers that
contain the IC’s basic instructions for setting up the IC
configuration, output voltages, sequencing, fault
thresholds, fault masks, etc. These registers are what
give the IC its operating flexibility. The two types of
registers are described below.
Basic Volatile – These are R/W (Read and Write) and
RO (Read only). After the IC is powered, the user can
modify the R/W register values to change IC
functionality. Changes in functionality include things like
masking certain faults. The RO registers communicate
IC status such as fault conditions. Any changes to these
registers are lost when power is recycled. The default
values are fixed and cannot be changed by the factory
or the end user.
The ACT4911 is highly flexible and contains many I2C
configurable functions. The IC’s default functionality is
defined by its default CMI (Code Matrix Index), but
much of this functionality can be changed via I2C. I2C
functionality includes storage voltage setting, OV and
UV fault thresholds, switching frequencies, ADC control
and automatic fault thresholds, PLI pin functionality,
health check settings, and current limits. The CMI Options section shows the default settings for each available CMI option. Contact [email protected] for additional information about other configurations.
Basic Non-Volatile – These are R/W and RO. After the
IC is powered, the user can modify the R/W register
values to change IC functionality. Changes in
functionality include things like output voltage settings,
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
14
ACT4911QW
Rev 1.0, 15-Sept-2017
startup delay time, and current limit thresholds. Any
changes to these registers are lost when power is
recycled. The default values can be modified at the
factory to optimize IC functionality for specific
applications. Please consult [email protected] for
custom options and minimum order quantities.
NORMAL State
When modifying only certain bits within a register, take
care to not inadvertently change other bits.
Inadvertently changing register contents can lead to
unexpected device behavior.
HEALTH CHECK State
The NORMAL state is the normal operating state after
startup with no faults. The eFuse is fully on, VOUT =
VIN, and the IC provides full operating current. Note that
the IC charges the storage capacitors to their
programmed value at the beginning of NORMAL state.
The HEALTH CHECK state can be considered a substate of NORMAL. The IC operates identical to the
NORMAL state with the addition of activating the
circuitry that check the storage capacitor health. The IC
automatically enters HEALTH STATE every four
minutes. The user may also manually enter this state by
writing a 1 into the FORCE_HLTHCHK bit which is bit 1
in register 0x0Ah. This bit automatically resets to 0 after
the health check routine completes. The IC
automatically exits HEALTH CHECK and enters
SUPPLEMENT state in a fault condition.
State Machine
ACT4911 contains an internal state machine with seven
internal states: UV/POR, SOFT-START, NORMAL,
HEALTH CHECK, SUPPLEMENT, SHUTDOWN1, and
SHUTDOWN2.
UV/POR State
The IC enters the UV/POR state on power up. It also
enters UV/POR from SUPPLEMENT state in the
following conditions:
SUPPLEMENT State
The IC enters SUPPLEMENT state when it detects a
fault condition. It opens the eFuse to bi-directionally
disconnect the input from the output. It automatically
turn on the buck converter to power the output from the
storage capacitors. The following five conditions move
the IC into SUPPLEMENT state.
1. When the input voltage drops below the EN_UV
threshold.
2. When the storage capacitor voltage drops
below 3.6V.
3. When the buck converter output voltage goes
OV or UV.
1.
2.
3.
4.
5.
The user may force the IC into UV/POR by writing a 1
into the FORCE_PWROFF bit, register 0x0Ah, bit 0.
When entering UV/POR from power up, all registers
reset to their default state. The registers retain their
existing values when the IC enters from SUPPLEMENT
state or from SHUTDOWN2 EFUSE. The IC transitions
to the SOFT-START state when EN pin is above 0.64V
and the input voltage is above UVLO.
EN voltage below UV threshold
EN voltage above the OV threshold
Input voltage above the OV threshold
eFuse current above the OC threshold
VIN – VOUT > 560mV
SHUTDOWN1 State
SHUTDOWN1 protects against over temperature
(145 °C), internal LDO failure, or boot capacitor failure.
The eFuse remains on and continues to provide power
to the output, but the boost converter is disabled. The
ADC remains on and I2C functionality is still operational.
The IC transitions to SHUTDOWN2 state if the die
temperature increases to 155°C. If transitions back to
the NORMAL state if the fault conditions go away.
SOFTSTART State
In the SOFTSTART state, the IC slowly turns on the
eFuse to minimize inrush currents. The output voltage
dV/dt ramp rate is controlled by the SS pin. The SS pin
directly controls the maximum output voltage dV/dt
while the ILIM pin indirectly controls it by limiting the
current into the output capacitance. The IC stays in the
SOFTSTART state until VIN-VOUT < 200mV and a
10ms timer times out. Note that the output voltage may
be fully charged up to VIN even though the IC in still in
the SOFTSTART state. The storage caps charge up to
the output voltage in this state.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
15
ACT4911QW
Rev 1.0, 15-Sept-2017
SHUTDOWN2 State
operating state can be determined by reading the I2C
register bits CURRENT_STATE in register 0x00h.
SHUTDOWN2 disables all IC functionality to protect
against extreme over temperature conditions above
155°C. This includes shutting off the eFuse. I2C
functionality not available in this state. The IC transitions
to SOFT-START when the junction temperature drops
and there is no overcurrent fault. Figure 3 shows the
ACT4911 State Diagram. Table 1 shows which functions
are enabled in each state. Note that the current
UV/POR
EN UV
Storage cap < 3.6V
Buck output U V/OV
Buck OC
LDO UV
Compensation pin shot to GND
EN > UV
& VIN > UVLO
Optional
Timer
125ms
Soft‐
Start
Mode
Supplement
Mode
Repeat every 4min
Storage Cap
is Filled to
PG_THR
eFuse over current
TJ > 155°C
VIN ‐ VOUT < 200mV
Soft‐start done
EN UV/OV
VIN OV
eFuse OC
VIN ‐ VOUT > 560mV
Health
Check
Mode
eFuse not in OC
& TJ < 155°C
& 100ms delay
Normal
Mode
Shutdown2
eFuse
eFuse over current
TJ > 155°C
TJ > 155°C
& go to Shutdown2
when T J > 155°C
TJ < 135° C
& LDO not UV
& Storage cap not OV
& Boot cap not fail
Shutdown1
Boost
TJ > 135° C
LDO UV
Storage cap OV
Boot cap fail
Figure 3: State Machine Diagram
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
16
ACT4911QW
Rev 1.0, 15-Sept-2017
States
eFuse
Boost
Buck
ADC
VREF
UV/POR
Disabled
Disabled
Disabled
Disabled
Disabled
SOFT-START
Enabled
Disabled
Disabled
Disabled
Enabled
NORMAL
Enabled
Enabled
Disabled
Enabled
Enabled
HEALT CHECK
Enabled
Enabled
Disabled
Enabled
Enabled
SUPPLEMENT
Disabled
Disabled
Enabled
Enabled
Enabled
SHUTDOWN1
Enabled
Disabled
Disabled
Enabled
Enabled
SHUTDOWN2
Disabled
Disabled
Disabled
Disabled
Disabled
Table 1: Enabled Functions in Different States
EN_UV
VIN
0
Buck_UV
VOUT
0
Boost
Enabled
(I2C)
VSTR
0
PLI
0
nIRQ
10ms Delay
10ms Delay
0
Soft Start
Supplement
Mode
Boost On
Soft Start
Boost On
Figure 4: Operation states
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
17
ACT4911QW
Rev 1.0, 15-Sept-2017
STR
Pin Functions
STR is the output to the storage capacitor bank. In
normal operation the internal boost converter charges
the storage capacitors through the STR pin. When the
IC enters supplement mode, the internal buck converter
uses the STR pin as its input to power the system. The
STR pin typically has a 22uF or greater ceramic
capacitor. See the Buck Converter section for more
information.
VIN
VIN is the input the eFuse. Connect a 0.1uF ceramic
capacitor between VIN and PGND. VIN is directly
connected to VOUT in normal operation. The eFuse
disconnects VIN from VOUT when the IC enters
supplement mode.
EN
IRQ—Interrupt
The EN pin is the ACT4911 enable input used to turn
the eFuse on or off. It provides both overvoltage and
undervoltage protection thresholds. The EN pin
contains a precision comparator with hysteresis. It can
be directly driven from a digital input to turn the eFuse
on and off. The EN pin can also be used with a resistor
divider from VIN to VSS to program an eFuse startup
voltage higher than the IC’s UVLO value. The EN pin
also contains an overvoltage comparator. The eFuse
turns on when the input EN pin goes above the
EN_UV_REF threshold. Once the eFuse is on, it turns
off and enters supplement mode if the EN pin goes
above the EN_OV_REF threshold or below the
EN_UV_REF threshold.
ACT4911 has an interrupt pin to inform the host of any
fault conditions. In general, any IC function with a status
bit asserts nIRQ if the status changes. The status
changes can be masked by setting the corresponding
register bits. If nIRQ is asserted low, the fault must be
read before the IC deasserts nIRQ. If the fault remains
after reading the status bits, nIRQ remains asserted.
The below status changes will set the IRQ:











The EN pin should not be left floating. It can be driven
from standard logic signals greater than EN_UV_REF.
It can also be driven with open-drain logic to provide.
When driving it with an open-drain, ensure that the
pullup voltage is not higher than the EN_OV_REF
setting.
EN_UV_REF is fixed at 0.64V. However, the
EN_OV_REF can be programmed by I2C bits
EN_OV_REF [2:0]. The default EN_OV_REF voltage is
set by the IC’s CMI.
nIRQ is an open-drain output and should be pulled up
to an appropriate supply voltage with a 10kΩ or greater
pull-up resistor.
SCL, SDA
Table 2: Over Voltage Reference Settings
EN_OV_REF[2:0]
OV Threshold (V)
000
Disabled
001
0.82
010
0.92
011
1.00
100
1.08
101
1.16
110
1.24
111
1.32
Input overvoltage, undervoltage
Thermal warning, thermal shutdown
eFuse VIN to VOUT over limits
eFuse current warning and limit
Storage capacitor overvoltage, undervoltage
Supplemental mode active
Buck operation faults
Buck undervoltage shutdown
REF LDO undervoltage
ADC data is ready
ADC beyond set limits
SCL and SDA are the I2C clock and data pins to the IC
They have standard I2C functionality. They are opendrain outputs and each require a pull-up resistor. The
pull-up resistor is typically tied to the system’s uP IO
pins. The pullup voltage can range from 1.8V to 5.0V.
REF
The REF pin is an internal bias voltage output pin.
Connect a 1µF capacitor between REF and VSS. Do
not apply an external load to the REF pin.
BSET
BSET sets the boost converter output voltage. The
output voltage is a function of both a resistor connected
between BSET and VSS as well as internal I2C register
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
18
ACT4911QW
Rev 1.0, 15-Sept-2017
settings. See the Storage Boost Converter section for
more information.
operation. The IC exits softstart ~10ms after the
programmed softstart time ends.
ISET
PLI_VOUT_READY function. Set PLI_FUNC_SEL = 11
to configure PLI for this function. With this setting, PLI
performs a dual function. It starts out as the
VOUT_READY function at turn-on. After PLI goes from
low to high after softstart, it then acts as the Power Loss
Indicator function.
ISET sets the eFuse current limit with a resistor
connected to VSS. See the eFuse section for more
information.
SS
The SS pin uses a capacitor to VSS to control the eFuse
softstart timing. See the eFuse section for more
information.
The PLI pin is an open-drain output and is 24V
compliant.
FB
PGND
The FB pin is used to regulate the buck converter output
voltage when the IC is in supplement mode.
The PGND pin is the buck and boost converters’ power
ground. The internal FETs connect directly to the PGND
pins. The power supply input and output capacitors
should connect to the PGND pins.
HSB
HSB provides power to the internal high-side MOSFET
gate driver circuitry. Connect a 47nF capacitor from
HSB pin to SW pin.
COMP
COMP is the output of a transconductance amplifier that
is used to compensate the internal buck converter. The
compensation components, which are typically a
standard type-2 compensation should be grounded to
the VSS pin. See the Application section for more
information on compensating the internal buck
converter.
SW
SW is the switch node for the internal buck and boost
converters.
VOUT
VOUT is the output of the eFuse and connects to the
system load. VOUT powers the boost converter when
it charges up the storage capacitors. It is the output of
the buck converter when the IC is in supplement
mode. The eFuse connects VOUT to VIN in normal
operation, and it disconnects it in supplement mode.
PLI
The PLI pin has four possible functions which are set by
the internal I2C registers.
Power Loss Indicator function. Set register bits
PLI_FUNC_SEL[1:0] in 0x19h to 00 to configure PLI for
this function. With this setting, PLI goes high after
softstart and stays high in normal operation. PLI
immediately goes low when the IC enters supplement
mode. This setting is used to let the system uP know
that power loss is imminent.
PG_STR function. Set PLI_FUNC_SEL = 01 to
configure PLI for this function. With this setting, PLI
starts low during softstart and then goes high when the
storage capacitor voltage is in regulation. It goes low if
the storage voltage drops below 95% of its programmed
output voltage.
VOUT_READY function. Set PLI_FUNC_SEL = 10 to
configure PLI for this function. With this setting, PLI
starts low during softstart and then goes high when the
IC exits the softstart mode and goes into normal
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
19
ACT4911QW
Rev 1.0, 15-Sept-2017
EFUSE
14.000
12.000
The ACT4911 eFuse is an “electronic” fuse that
disconnects the input from the output. It has
considerable advantages over mechanical fuses
because it has adjustable current thresholds and it
resets after the fault condition is gone. The eFuse
consists of two back-to-back MOSFETS to provide bidirectional protection. This provides protection against
both input and output short circuit conditions by
preventing current flow in both directions. Hot swap
functionality is provided by the eFuse softstart function
and current limiting circuitry. This prevents large inrush
currents from pulling down the input voltage. The eFuse
also provides protection against high input voltage
transients up to 24V by opening when the input voltage
goes above the programmed threshold.
10.000
Output Current (A)
General Description
6.000
4.000
2.000
0.000
0
10
20
30
40
50
60
RISET (kΩ)
Figure 5: Current Limit Threshold vs RILIM
Note that the eFuse current can be measured using the
ILIM pin. If eFuse current is measured via the ILIM pin,
the measurement circuit must have a high impedance
input to minimize errors. The current flowing out of ILIM
is 1/50000 of the current through the eFuse. The
following equation calculates the eFuse current when
measured via the ILIM pin.
The eFuse turns off in the following conditions.
1.
2.
3.
4.
5.
8.000
EN voltage below UV threshold
EN voltage above the OV threshold
Input voltage above the OV threshold
eFuse current above the OC threshold
VIN – VOUT > 560mV
∗
Equation (2)
Where RILIM is the current limit resistor in ohms and VILIM
is the voltage on the ILIM pin in volts.
Current Limit Setting
When the eFuse reaches the current limit threshold, it
clamps the output current. If the load tries to draw
additional current, the eFuse opens.
A resistor connected between the ISET pin and VSS
program the ACT4911 eFuse inrush and maximum DC
current limits. The input current limit is linearly
proportional to the resistor value on the ISET pin. The
following equation calculates the correct resistor value
to get the desired current limit threshold.
Soft-Start
The SS pin controls the eFuse start-up. The SS pin
drives a constant 5μA internal current source into the
external soft-start capacitor to provide a linear ramping
voltage at the SS pin. The output voltage linearly ramps
with the SS pin voltage, resulting in a well-controlled
linear softstart ramp on VOUT, regardless of the load
conditions. The following equation calculates the
required soft-start capacitance.
Equation (1)
Where RILIM is the current limit resistor in ohms and IILIM
is the desired current limit threshold in Amperes. Figure
5 shows the current limit setting vs RILIM value.
Equation 2
Where the TSS is the soft-start time in ms and VOUT is the
output voltage.
The softstart current must be less than 90% of the
programmed eFuse current limit. If the softstart current
is greater than 90% of the eFuse current limit, the IC
enters the SHUTDOWN2 state, turns off the eFuse, and
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
20
ACT4911QW
Rev 1.0, 15-Sept-2017
then retries to softstart again. The following equation
calculates the minimum allowable softstart time.
∗
_
. ∗
Where FSW_max is the maximum allowable frequency,
VSTR is the storage voltage, and VOUT is the output
voltage during supplement mode.
Equation 3
Output Voltage Setting
The buck converter output voltage is programmed by an
external resistor divider connected between the VOUT
pin and VSS, with the center tap connected to the FB
pin. The buck output voltage can be set above, below,
or equal to the input voltage supplement threshold.
When the input voltage drops below this threshold, the
IC enters supplement mode and regulates the output to
the programmed buck voltage. Although the buck
converter immediately starts up when the IC enters
supplement mode, the output voltage still has a small,
but finite drop in output voltage between the time the
eFuse turns off and the buck converter is fully on. This
voltage drop should be considered when setting the
output voltage. The following equation calculates the
correct resistor values to set the desired output voltage.
Where COUT is the sum of the output capacitance and
storage capacitance in mF, VOUT is the output voltage in
volts, and IILIM is the eFuse current limit in Amperes
programmed by the ILIM resistor.
Buck Converter
General Description
The ACT4911 contains current-mode, synchronous
PWM step-down converter that achieves peak
efficiencies of 95%. The buck converter minimizes noise
in sensitive applications and allows the use of small
external components. It is highly flexible with external
component selection and can be reconfigured via I2C
registers. External components set the output voltage
and compensation while I2C registers set the switching
frequency and current limit. The buck converter
operates in fixed frequency PWM mode. Its switching
frequency is programmable between 320kHz to 1130
kHz via the I2C register BK_FREQ[2:0] which allows the
system to be optimized for different applications. Its
current limit is adjustable between 5A to 9A, allowing for
further system optimization. The output voltage is
externally programmable between 1.8V and 8V.
1
Equation 4
Protection
The buck converter has several protection mechanisms
to insure safe operation. It stops operation when input
voltage from storage cap reaches STR_UVLO (3.6V) or
when the output voltage drops below the power good
threshold which is fixed at 93% of the output setpoint. It
also stops operating when the output voltage is above
the over voltage threshold which is fixed at 110% of the
output voltage setpoint. The output undervoltage
protection can be masked by the I2C register bit
Mask_BK_UV REG0x38 [0].
Frequency Setting
Higher switching frequencies result in smaller solution
sizes at the cost of slightly lower efficiency. Lower
switching frequencies result in larger solution sizes
with higher efficiency. The maximum allowable
switching frequency for any given design is limited by
the following equation.
∗
1
Where R1 is the top feedback resistor, R2 is the bottom
feedback resistor, VOUT is the desired output voltage,
and VFB is the fixed 1.2V reference voltage on the FB
pin. Choose R2 in the range of 10kohm. Smaller
resistor values are acceptable, but larger values will
affect voltage accuracy due to bias currents into the FB
pin.
The buck converter generates a regulated output
voltage at the VOUT pin from the storage capacitors
when the IC enters supplement mode. This provides the
backup power when the system experiences fault
conditions. After the IC exits the SOFTSTART state, the
buck converter is enabled but remains turned off. It
automatically turns on when the IC enters supplement
mode, and remains on until the storage capacitors
discharge to 3.6V.
_
R2 ∗
The buck converter provides overcurrent and short
circuit protection. Overcurrent protection is achieved
with cycle-by-cycle current limiting. The peak current
threshold is set between 5A and 9A by the BK_CLIM bits.
If the peak current reaches the programmed threshold,
the IC turns off the power FET. This condition typically
results in shutdown due to an output voltage UV
condition due to the shortened switching cycle.
Equation 3
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
21
ACT4911QW
Rev 1.0, 15-Sept-2017
Table 3: Buck Current Limit
from the capacitor to PGND should as short and wide
as possible.
BK_CLIM[1:0]
ILIMSET (A)
00
5.0
Inductor Selection
01
6.0
10
7.0
11
9.0
The Buck regulator utilizes current-mode control and a
proprietary internal compensation scheme to
simultaneously simplify external component selection
and optimize transient performance over their full
operating range. These ACT4911 is optimized for
operation with 1uH to 3.3uH inductors. Choose an
inductor with a low DC-resistance, and avoid inductor
saturation by choosing inductors with DC ratings that
exceed the maximum output current by at least 30%.
Due to the requirement for the buck converter to start
up as quickly as possible, the inductor should be
designed to give a maximum ripple current, ΔIL, of 50%
to 60% of the maximum output current. The following
equation calculates the recommended inductor value.
A short circuit condition that results in the peak switch
current being 122.5% of BK_CLIM immediately shuts
down the supply and asserts nIRQ low. A buck
overcurrent, undervoltage, or overvoltage condition
moves the IC into the UV/POR state.
Compensation
The Buck regulator utilizes type 2 external
compensation placed on the COMP pin. Contact the
factory for compensation details.
∗
∗∆
Input Capacitor Selection
Where L is the inductor value in µH, VOUT is the output
voltage, VSTR is the maximum storage voltage, FSW is
the switching frequency in Hz, and ΔIL is the desired
ripple current in Amperes.
The STR pin is the input voltage to the buck converter.
It requires a dedicated high quality, low-ESR, ceramic
input capacitor that is optimally placed to minimize the
power routing. For optimal PCB layout considerations,
1206 or 1210 sized input capacitors are recommended.
A 22uF capacitor is typically suitable, but the actual
value is application dependent. The input capacitor can
be increased without limit. Choose the input capacitor
value to keep the input voltage ripple less than 50mV
∗
Output Capacitor Selection
The buck converter is designed to take advantage of the
benefits of ceramic capacitors, namely small size and
very-low ESR. The buck converter is designed to
operate with 44µF output capacitor over most of its
operating ranges, although more capacitance may be
desired depending on the duty cycle and load step
requirements. Choose a ripple voltage that is
approximately 1% of the output voltage setpoint. Note
that the output capacitance must be placed at the output
of the buck converter. Additional downstream
capacitance will be placed at the loads, but this
capacitance should not be considered when calculating
the buck output capacitance. However, the downstream
capacitance should be considered when compensating
the power supply. The following equation calculates the
output voltage ripple as a function of output capacitance.
Note that the worst case ripple voltage occurs at the
beginning of supplement mode when the storage
capacitors are fully charged.
∗
∗
Equation 6
Equation 5
Where Iout is the maximum eFuse load current in
Amperes, VSTR is the maximum storage voltage, FSW is
the switching frequency, and Vripple is the maximum
allowable ripple voltage on the input of the buck
converter. Note that the storage capacitor values should
not be considered when calculating the input voltage
ripple because they are not typically designed for high
frequency functionality.
Be sure to consider the input capacitor’s DC bias effects.
A capacitor’s actual capacitance is strongly affected by
its DC bias characteristics. The input capacitor is
typically an X5R, X7R, or similar dielectric. Use of Y5U,
Z5U, or similar dielectrics is not recommended. Input
capacitor placement is critical for proper operation. The
buck’s input capacitor must be placed as close to the IC
as possible. The traces from STR to the capacitor and
COUT
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
∆
∗
∗
Equation 7
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
22
ACT4911QW
Rev 1.0, 15-Sept-2017
Where Vripple is the desired output ripple voltage, FSW is
the switching frequency in Hz, and ΔIL is the maximum
ripple current in Amperes.
Operating Mode
The boost converter operates in peak current mode,
non-fixed frequency mode. The power FET stays on
until its current reaches programmed peak current. It
then turns off until the inductor current drops to 0A, at
which time it turns on again.
As with the input capacitor selection, use X5R or X7R
dielectrics and be sure to consider the capacitor’s DC
bias effects.
Storage Capacitor Voltage Setting
Storage Boost Converter
The buck converter output voltage is set by either the
I2C register BSTVSET[4:0], or a combination the
register and a resistor placed between the BSET pin to
VSS.
General Description
The ACT4911 contains an integrated peak currentmode, synchronous boost converter. It minimizes
system level costs by using the same components as
the buck converter. The peak current is adjustable
between 250mA and 950mA, allowing for system
optimization. The output voltage is adjustable between
5V and 36V via I2C registers and an external resistor.
The peak current-mode control topology eliminates the
need for compensation. The boost automatically
charges up the storage capacitors from the input
voltage so they are ready to provide backup power in
the event of a system fault.
When using only the BSTVSET[4:0] leave the BSET pin
floating. Table 5 shows the programmed storage voltage.
The default value is determined by the IC’s specific CMI
option.
Table5: Storage Capacitor Voltage Settings with
BSET Pin Open
0
5V
5.6V
7V
8V
9V
10V
11V
12V
13V
14V
15V
16V
17V
18V
19V
20V
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
Startup
The boost converter automatically starts when the IC
exits the SOFTSTART state. Note that the IC exits the
SOFTSTART state 10ms after the output voltage is
within 200mV of the input voltage.
When the storage voltage reaches regulation, the boost
enters standby mode and monitors the storage voltage.
It automatically turns back on and “tops off” the storage
capacitors when the storage voltage drops below 95%
of the programmed voltage. The boost converter
automatically turns off if it is “topping off” the storage
capacitors when the IC enters supplement mode.
The average input current when the boost charges the
storage capacitors is approximately ½ of the peak
switching current. The peak switch current is programed
by register BST_CLIM[1:0].
1
21V
22V
23V
24V
25V
26V
27V
28V
29V
30V
31V
32V
33V
34V
35V
36V
Using both the BSTVSET[4:0] register and an external
resistor provides additional output voltage resolution. In
this configuration, the following equation calculates the
output voltage.
Table 4: Boost Peak Current Settings
BST_CLIM[1:0]
00
01
10
11
BSTVSET[4]
BSTVSET[3:0]
(mA)
250
650
950
1500
∗
Ω
Equation 8
Where VBSTVSET is the voltage set by the BSTVSET
register in Table 5 and RBSET is the resistor on the BSET
pin in ohms.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
23
ACT4911QW
Rev 1.0, 15-Sept-2017
As an example, with BSTVSET[4:0] = 10111 (sets
VBSTVSET = 28V) and RBSET = 34.2kΩ, VSTR = 12.8V. Note
that RBSET should be set between 20kΩ and 75kΩ.
Setting RBSET below 20kΩ gives the same result as
using a 20kΩ resistor. Setting RBSET above 75kΩ gives
the same result as using a 75kΩ resistor. Using RBSET
outside the range is acceptable and does not damage
the IC.
HMON_THR[2:0]
Input Capacitor Selection
There are no special considerations for the boost
converter input capacitor. The IC topology uses the
buck converter output capacitor for the boost input
capacitor. Proper selection of the buck converter output
capacitor automatically results in an acceptable boost
converter input capacitor.
HMON_THR[3]
0
1
000
95.0%
96.6%
001
95.2%
96.8%
010
95.4%
97.0%
011
95.6%
97.2%
100
95.8%
97.4%
101
96.0%
97.6%
110
96.2%
97.8%
111
96.4%
98.0%
Storage Capacitor Health Monitor
Output Inductor Selection
General Description
There are no special considerations for the boost
converter inductor. The IC topology uses the buck
converter inductor for the boost converter inductor.
Proper selection of the buck converter output capacitor
automatically results in an acceptable boost converter
input capacitor.
The ACT4911 has an internal health monitor for the
storage capacitors. It applies a constant current sink to
the capacitors and monitors the voltage drop. If the
voltage drops below a predetermined threshold, the IC
asserts nIRQ to indicate that the storage capacitance
has dropped below the allowable threshold. Health
monitoring is completely autonomous, but can also be
manually initiated by the system uP. Health monitoring
can also be configured so that it is only a manual
operation so it can be triggered on demand to avoid any
critical system operations. The health monitor
parameters are adjustable via I2C registers to allow
flexibility for different capacitor values.
Output Capacitor Selection
The IC topology uses the buck converter input capacitor
for the boost converter output capacitor. Note that the
storage capacitors are also included in the boost
converter output capacitors. Proper selection of the
buck converter input capacitor typically results in an
acceptable boost converter output capacitor. The boost
output capacitor has two criteria. The first is that it must
consist of at least 10µF of high quality X5R or X7R
ceramic capacitance placed directly between the STR
pin and PGND. The second criteria is that the sum of
the ceramic capacitor and storage capacitors must be
greater than 100µF. There is no requirement for the
additional capacitance dielectric material. This provides
flexibility for the storage capacitors, which allows the
use of super capacitors, electrolytic, polymer, Tantalum,
ceramic, or any capacitors in the design.
Health Monitor Algorithm
The health check algorithm sinks 10mA into the STR pin
for a time determined by I2C register HMON_TSET. It
then sinks 50mA for 200us. It monitors the voltage on
the STR pin, and if the voltage drops more than the
percentage set by I2C register HMON_THR, it asserts
nIRQ low and sets the fault bit. The IC’s specific CMI
option sets the default HMON_TSET and HMON_THR
settings. After the HMON_TSET time, the boost turns
back on to recharge the storage capacitor.
Output Voltage UVLO Setting
The health check function can be enabled and disabled
by the DIS_HEALTH_CHK bit (0x1Fh [5]). It also can be
forced to perform a one-shot health check by the
FORCE_HLTHCHK bit (0x0Ah [1]). Forcing a single
health check is valid even when the DIS_HEALTH_CHK
bit =1. If set in continuous mode, the IC performs a
health check every 4 minutes. This timing can be
configured for every 8 minutes or 16 minutes by bits
SCALE_HCHK _2X and SCALE_HCHK _4X in register
0x27h [1:0].
The storage capacitor power good signal indicates that
the STR voltage is above the UVLO threshold. The
UVLO threshold is shared with the storage capacitor
health check, and is set by the I2C register HMON_THR
[3:0]. The default value is determined by the IC’s
specific CMI option.
Table 6: Storage Capacitor PG Threshold
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
24
ACT4911QW
Rev 1.0, 15-Sept-2017
The ACT4911 allows for very flexible health checking
routines by allowing the system to manually enable the
10mA
discharge
current
by
setting
the
EN_STR10mASINK bit = 1. In this situation, the system
manually turns the discharge current on and off. The
storage capacitor voltage threshold is still determined
by the HMON_THR register. This function is useful for
checking extremely large capacitor values which need
very long discharge times.
V
VSTR
uses an analog input multiplexer to select one of six
channels for the A/D conversion. The resulting digital
results are stored in six digital registers. A six to one
multiplexer connects one of the ADC output registers to
the user accessible register map.
ADC Configuration
The ACT4911 ADC is configured through the I2C
interface. It is enabled and disabled by the EN_ADC
register bit. The ADC has two conversion modes,
manual single-shot conversion and automatic polling
conversion.
Storage Cap Voltag e
PG_THR
(Programmable)
Single-Shot Conversion
Pr ogrammable
Interval Time
0
Configure the IC for single-shot conversion mode by
setting the following I2C bits in register 0x08h
t
I
Pr ogrammable
Discharge Time
50mA
ADC_ONE_SHOT = 1.
ADC_CH_SCAN = 0
EN_ADCBUF = 1
200us
10mA
Discharge Current
0
Health Testing
Initial Charge
Top-Off
Maintain
t
In single shot mode, the user defines the input channel
to be converted and then manually initiates the ADC
conversion. I2C bits ADC_CH_CONV [2:0] in register
0x08h select the input channel to be converted.
ADC_CH_READ [2:0] selects the ADC channel to be
read. These should be set to the same channel. The
user initiates an ADC read by writing a 1 into EN_ADC
in register 0x08h. When ADC conversion is complete,
the ADC_DATA_READY bit (register 0x07h [7]) is set to
1, nIRQ is asserted low, and EN_ADC automatically
changes back to 0. The uP can then read the status bits
to find that the ADC conversion is complete. The ADC
data are stored in ADC_DOUT [13:6] in register 0x05h.
nIRQ stays asserted low and the ADC_READY_BIT
stays equal to 1 until the ADC data is read. Reading the
ADC data automatically deasserts nIRQ. To initiate
another ADC conversion for the same channel, set
EN_ADC=1. To initiate an ADC conversion for another
channel,
change
ADC_CH_CONV
and
ADC_CH_READ to the appropriate channel and then
set EN_ADC=1.
Figure 6: Storage Voltage at Different Stages
The register HMON_TSET [3:0] sets the health check
discharge time as shown in Table 7. This also allows the
use of the ADC to check the slope of the discharge and
calculate the capacitance.
Table 7: Health Check Discharge Time
HMON_TSET[2:0]
HMON_TSET[3] (ms)
0
1
000
2
384
001
4
512
010
8
640
011
16
768
100
32
896
101
64
1024
110
128
1152
111
256
1280
ADC Monitoring
General Description
The ACT4911 contains a built-in analog to digital converter, ADC, which can be used to monitor five system
level parameters. These include input voltage, output
voltage, storage capacitor voltage, eFuse current, and
die temperature. It is a single 8 bit delta-sigma ADC that
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
25
ACT4911QW
Rev 1.0, 15-Sept-2017
ADC_ONE_SHOT = 0
ADC_CH_SCAN = 1
EN_ADCBUF = 1
CH0
CH1
CH2
6 to 1
MUX
8 Bit
Result
ADC
Start the automatic polling by changing EN_ADC to 1.
When in automatic polling mode, the ADC continuously
changes the MUX inputs to read all input channels. The
ADC continually overwrites the data in the output
register. After all channels have been converted, the
ADC_DATA_READY bit is set to 1. Note that nIRQ is not
asserted low in Automatic Polling mode. Ensure that
ADC data is valid and ready by reading the
ADC_DATA_READY before reading ADC data. After the
ADC_DATA_READY bit is set to 1, the user defines the
channel to be read with the ADC_CH_CONV [2:0] bits
in register 0x08h. Change ADC_CH_CONV to read
additional channels.
CH5
Clock
SEL[2:0]
Figure 7: ADC Block Diagram
Automatic Polling Conversion
Configure the IC for automatic polling conversion mode
by setting the following I2C bits in register 0x08h
Table 8: ADC Channels
Channel
Channel Description
ADC_CH_CONV[2:0]
ADC_CH_READ[2:0]
Value
CH0
Input Current
000
000
IIN = (DOUT-128)*1.221/RILIM (A)
CH1
Input Voltage
001
001
VIN = (DOUT-128)*0.392 (V)
CH2
Storage Cap Voltage
010
010
VSTR = (DOUT-128)*0.392 (V)
CH3
Output Voltage
011
011
VOUT = (DOUT-128)*0.392 (V)
CH4
Die Temperature
100
100
Temp = 6.125*DOUT-1053.75 (deg C)
CH5
GND
101
101
Disable a channel’s supervisory function by
programming the undervoltage register value to 0x00h
and the overvoltage register to 0xFFh.
Autonomous ADC Supervisory Function
The ACT4911 can be configured to automatically
measure any or all of the five system level parameters
and then then automatically notify the system if one of
the parameters falls out of its specified range. This
check is performed automatically, without any external
circuit components. The ACT4911 implements this
using internal digital undervoltage and overvoltage
comparators for all five ADC channels. Table 9 shows
each ADC channel’s undervoltage and overvoltage
registers. When in automatic polling mode, if an ADC
conversion result is below the undervoltage threshold or
above the overvoltage threshold, the IC asserts nIRQ
low. The uP can then read the status register 0x04h to
determine which parameter is out of range. nIRQ can
be masked by setting the ADC_OUTRNG_IRQ_MASK
bit. The default thresholds are determined by each ICs
CMI, but can be changed at any time after startup.
Table 9: ADC Thresholds Registers
Undervoltage
Overvoltage
Threshold Register Threshold Register
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
Input Current
0x0Ch
0x14h
Input Voltage
0x0Dh
0x15h
Storage Cap Voltage 0x0Eh
0x16h
Output Voltage
0x0Fh
0x17h
Die Temperature
0x10h
0x18h
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
26
ACT4911QW
Rev 1.0, 15-Sept-2017
4. The FB pin should be Kelvin connected to the
output capacitor through the shortest possible
route, while keeping sufficient distance from
switching node to prevent noise injection. The
IC regulates the output voltage to this Kelvin
connection.
PC board layout guidance
Proper parts placement and PCB layout are critical to
the operation of switching power supplies. Follow the
following layout guidelines when designing the
ACT4911 PCB. Refer to the Active-Semi ACT4911
Evaluation Kits for layout examples
5. Connect the PGND and VSS ground pins must
be electrically connected together. The VSS
ground plane should be isolated from the rest
of the PCB power ground.
1. Place the buck input capacitors as close as
possible to the IC. Connect the input capacitors
directly between STR and PGND pins on the
top layer. Routing these traces on the top layer
eliminates the need for vias.
6. Remember that all open drain outputs need
pull-up resistors.
2. Minimize the switch node trace length between
the SW pin and the inductor. Optimal switch
node routing is to run the trace between the input capacitor’s pads. Using 1206 or larger sized
input capacitors is recommended. Avoid routing
sensitive analog signals near these high frequency, high dV/dt traces.
7. Connect the exposed pad directly to the top
layer ground plane. Connect the top layer
ground plane to both internal ground planes
and the PCB backside ground plane with thermal vias. Provide ground plane routing on multiple layers to allow the IC’s heat to flow into the
PCB and then spread radially from the IC. Avoid
cutting the ground planes or adding vias that restrict the radial flow of heat.
3. The Buck output capacitors should be placed
by the inductor and connected directly to the inductor and ground plane with short and wide
traces. The output capacitor ground should
make a short connection to the input capacitor
ground. If required, use multiple vias.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
27
ACT4911QW
Rev 1.0, 15-Sept-2017
Typical Operating Characteristics
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
28
ACT4911QW
Rev 1.0, 15-Sept-2017
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
29
ACT4911QW
Rev 1.0, 15-Sept-2017
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
30
ACT4911QW
Rev 1.0, 15-Sept-2017
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
31
ACT4911QW
Rev 1.0, 15-Sept-2017
CMI OPTIONS
This section provides the basic default configuration settings for each available ACT4911 CMI option. Refer to each
option’s application note for the comprehensive list of default settings
CMI 301: ACT4911QW301
CMI 301 is designed for standard 3.3V and 5V applications. CMI 301 default settings are appropriate for most typical
applications. Table 10 shows the default register settings.
Table 10: CMI 301 Default Register Settings
Function
Value
Register
Register Settings
PLI Pin Function
PLI & VOUT OK
0x19h
PLI_FUNC_SEL[1:0] = 11
Health Monitor Time
32ms
0x1Fh
HMON_TSET[3:0] = 0100
Health Monitor Threshold
95%
0x20h
HMON_THR[3:0] = 0000
Enable Overvoltage Reference
0.92V
0x20h
EN_OV_REF[2:0] = 010
Startup Delay
0ms
0x20h
EN_STARTDELAY = 0
Latch Supplement Mode
Yes
0x21h
EN_LATCH_SPLMNT = 1
Boost Current Limit
950mA
0x21h
BST_CLIM[1:0] = 10
Boost Voltage
28V
0x21h
BST_VSET[4:0] = 10111
Buck Peak Current Limit
9A
0x26h
BK_CLIM[1:0] = 11
Buck Switching Frequency
900kHz
0x28h
BK_FREQ[2:0] = 110
I2C Address
The CMI 301 7-bit I2C address is 0x3Ah. This results in 0x74h for a write address and 0x75h for a read address.
Device ID
The CMI 301 Device ID (register 0x3Bh) = 0x01h. This can be used to distinguish between different CMI versions.
Autonomous ADC Supervisory Function
The autonomous ADC supervisory function is disabled by default. All undervoltage register value are set to 0x00h and
all overvoltage register values are set to 0xFFh.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
32
ACT4911QW
Rev 1.0, 15-Sept-2017
PACKAGE OUTLINE AND DIMENSIONS QFN5X5-28
Top View
Side View
Bottom View
ACT88320 LAND PATTERN
See Active Semi Application note AN-104, QFN PCB Layout Guidelines for more information on generating the
ACT4911 land pattern.
Innovative PowerTM
ActiveSwitcherTM is a trademark of Active-Semi
www.active-semi.com
Copyright © 2017 Active-Semi, Inc.
33
Similar pages