LTC4281 - Hot Swap Controller with I2C Compatible Monitoring

LTC4281
Hot Swap Controller with I2C
Compatible Monitoring
Features
Description
Allows Safe Board Insertion Into Live Backplane
nn 12-/16-Bit ADC with ±0.7% Total Unadjusted Error
nn Monitors Current, Voltage, Power and Energy
nn Internal EEPROM for Nonvolatile Configuration
nn Wide Operating Voltage Range: 2.9V to 33V
nn I2C/SMBus Digital Interface (Coexists with PMBus
Devices)
nn 12V Gate Drive for Lower MOSFET R
DS(ON)
nn Programmable Current Limit with 2% Accuracy
nn MOSFET Power Limiting with Current Foldback
nn Continuously Monitors MOSFET Health
nn Stores Minimum and Maximum Measurements
nn Alerts When Alarm Thresholds Exceeded
nn Reboots on I2C Command
nn Input Overvoltage/Undervoltage Protection
nn Three General Purpose Input/Outputs
nn Internal ±5% or External Timebases
nn 28-Pin 4mm × 5mm QFN Package
The LTC®4281 Hot Swap controller allows a board to be
safely inserted and removed from a live backplane. Using
an external N-channel pass transistor, board supply voltage
and inrush current are ramped up at an adjustable rate.
An I2C interface and onboard ADC allows for monitoring
of board current, voltage, power, energy and fault status.
nn
The device features analog foldback current limiting to
limit the MOSFET power to a constant value. A wide input
voltage operating range comfortably allows applications
from 2.9V to 33V.
The LTC4281 is well suited to high power applications
because the precise monitoring capability and accurate
current limiting reduce the extremes in which both loads
and power supplies must safely operate. Non-volatile
configuration allows for flexibility in the autonomous
generation of alerts and response to faults.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Applications
Enterprise Servers and Data Storage Systems
Network Routers and Switches
nn Base Stations
nn Platform Management
nn
nn
Typical Application
12V, 65A Plug-In Board Resident Application
Start-Up Waveforms
VOUT
12V
65A
0.5mΩ
12V
+
10Ω
CONNECTOR 1
CONNECTOR 2
SMCJ15CA
SDA
SCL
ALERT
VDD ADC+ SENSE+
NC
NC
NC
12V
100k
UV
OV
SDAI
SDAO
SCL
ALERT
ADR0
ADR1
ADR2
ON INTVCC
SENSE– ADC– GATE
SOURCE
FB
LTC4281
TIMER
NC
GPIO1
POWER
GOOD
GPIO2
GP
GPIO3
GP
WP CLKIN CLKOUT GND
VDD
10V/DIV
CONTACT BOUNCE
∆VGATE
10V/DIV
50ms DE-BOUNCE
VSOURCE
10V/DIV
GPIO1(PG)
10V/DIV
20ms/DIV
4281 TA01b
4281 TA01a
4.7µF
10nF
NC
GND
BACKPLANE PLUG-IN
BOARD
4281f
For more information www.linear.com/LTC4281
1
LTC4281
ADC–
SENSE–
SENSE+
ADC+
VDD
TOP VIEW
UV
28 27 26 25 24 23
ON 1
22 GATE
OV 2
21 SOURCE
GND 3
20 FB
WP 4
19 GND
29
INTVCC 5
18 GPIO1
TIMER 6
17 GPIO2
CLKOUT 7
16 GPIO3
CLKIN 8
15 ALERT
SCL
SDAO
SDAI
9 10 11 12 13 14
ADR2
Supply Voltage VDD..................................... –0.3V to 45V
Input Voltages
GATE – SOURCE (Note 3)....................... –0.3V to 10V
SENSE+, ADC+, SENSE­–....... VDD – 4.5V to VDD + 0.3V
ADC–............................................ –0.3V to VDD + 0.3V
SOURCE.................................................. –0.3V to 45V
ADR0-2, TIMER......................–0.3V to INTVCC + 0.3V
CLKIN.................................................... –0.3V to 5.5V
UV, OV, FB, WP, ON, GPIO1-3,
SCL, SDAI.............................................. .–0.3V to 45V
Output Voltages
GATE, GPIO1-3, ALERT, SDAO................. –0.3V to 45V
CLKOUT.................................... –0.3 to INTVCC + 0.3V
Output Current INTVCC (VDD > 4V).........................25mA
Operating Ambient Temperature Range
LTC4281C................................................. 0°C to 70°C
LTC4281I..............................................–40°C to 85°C
Storage Temperature Range................... –65°C to 125°C
Pin Configuration
ADR1
(Notes 1, 2)
ADR0
Absolute Maximum Ratings
UFD PACKAGE
28-LEAD (4mm × 5mm) PLASTIC QFN
TJMAX = 125°C, θJA = 43°C/W
EXPOSED PAD (PIN 29) PCB CONNECTION OPTIONAL
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC4281CUFD#PBF
LTC4281CUFD#TRPBF
4281
28-Lead (4mm × 5mm) Plastic QFN
0°C to 70°C
LTC4281IUFD#PBF
LTC4281IUFD#TRPBF
4281
28-Lead (4mm × 5mm) Plastic QFN
–40°C to 85°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/. Some packages are available in 500 unit reels through
designated sales channels with #TRMPBF suffix.
4281f
2
For more information www.linear.com/LTC4281
LTC4281
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD = 12V unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Supplies
VDD
Input Supply Range
IDD
Input Supply Current
VDD(UVL)
Input Supply Undervoltage Lockout
VDD(HYST)
Input Supply Undervoltage Lockout Hysteresis
INTVCC
Internal Regulator Voltage
INTVCC(UVL)
INTVCC Undervoltage Lockout
INTVCC(HYST)
INTVCC Undervoltage Lockout Hysteresis
l
2.9
INTVCC Rising
V
mA
3.5
8
l
2.65
2.7
2.75
l
15
40
75
mV
l
3.1
3.3
3.5
V
l
2.45
2.6
2.7
V
l
50
110
175
mV
l
VDD Rising
33
V
Current Limit
∆VSENSE
Current Limit Voltage DAC Zero-Scale
VFB = 1.3V, ILIM = 000
VFB = 0V, ILIM = 000
l
l
12.25
3.4
12.5
3.75
12.75
4.1
mV
mV
Current Limit Voltage DAC Full-Scale
VFB = 1.3V, ILIM = 111
VFB = 0V, ILIM = 111
l
l
32.88
8.81
34.37
10.31
35.87
11.81
mV
mV
l
–0.05
0
0.05
LSB
0
±15
mV
Current Limit Voltage DAC INL
Fast Current Limit Comparator Offset
l
ISENSE–
SENSE– Pin Input Current
ISENSE+
SENSE+ Pin Input Current
VSENSE– = 12V
VSENSE+ = 12V
∆VGATE
Gate Drive (VGATE – VSOURCE) (Note 3)
IGATE
Gate Pull-Up Current
0
±1
µA
l
0
90
130
µA
VDD = 2.9V to 33V, IGATE = –1µA
l
10
12.5
13.5
V
Gate On, VGATE = 0V
l
–15
–20
–30
µA
l
Gate Drive
Gate Pull-Down Current
Gate Off, VGATE = 10V
l
0.5
1.3
3
mA
Gate Fast Pull-Down Current
∆VSENSE =100mV, ∆VGATE = 10V
l
0.3
0.9
3
A
tPHL(FAST)
Overcurrent to GATE Low
∆VSENSE =0mV Step to 100mV, C = 10nF
l
0.5
1
µs
VGATE
∆VGATE FET Off Threshold
5
8
10
V
l
Comparator Inputs
IIN
UV, OV, FB, ON WP Input Current
V = 1.2V
l
0
±1
µA
VTH-R
VDD, SOURCE Rising Threshold Voltages for
UV, Power Good (Note 6)
5%
10%
15%
l
l
l
–5
–10
–15
–7.5
–12.5
–17.5
–10
–15
–20
%
%
%
VTH-F
VDD, SOURCE Falling Threshold Voltages for
UV, Power Good (Note 6)
5%
10%
15%
l
l
l
–10
–15
–20
–12.5
–17.5
–22.5
–15
–20
–25
%
%
%
VTH-R
VDD Rising Threshold Voltages of OV (Note 6)
5%
10%
15%
l
l
l
10
15
20
12.5
17.5
22.5
15
20
25
%
%
%
VTH-F
VDD Falling Threshold Voltages of OV (Note 6)
5%
10%
15%
l
l
l
5
10
15
7.5
12.5
17.5
10
15
20
%
%
%
VTH
UV, OV, FB, ON Rising Threshold
l
1.26
1.28
1.3
V
VHYST
UV, OV, FB, ON Hysteresis
l
23
43
63
mV
VTH
FET-Bad FAULT VDS Threshold
l
150
200
270
mV
VTH
WP Pin Threshold Voltage
l
1.26
1.28
1.3
V
VHYST
WP Pin Hysteresis
l
2
20
35
mV
tPHL
Turn-Off Propagation Delay
l
10
25
45
µs
Falling
ON, UV, OV Turn-Off
4281f
For more information www.linear.com/LTC4281
3
LTC4281
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD = 12V unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
tPHL
Fast Turn On Propagation Delay
ON Pin Turn On
l
10
25
45
UNITS
µs
tD
Debounced Turn On Propagation Delay
UV, OV Turn On
l
45
50
55
ms
0.4
1
2
V
25
MHz
Crystal Oscillator
VTH
CLKIN Pin Rising Threshold
l
fMAX
Maximum CLKIN Pin Input Frequency
l
ICLKIN
CLKIN Pin Input Current
ICLKOUT
CLKOUT Pin Output Current
V = 0V to 3.3V
l
–10
10
µA
V = 0V to 3.3V
l
–150
150
µA
Falling
l
1.26
1.28
1.31
V
l
2
GPIO Pin Functions
VTH
GPIO, ALERT Threshold
VHYST
GPIO, ALERT Hysteresis
20
35
mV
0.3
0.4
V
0
±1
µA
VOL
GPIO, ALERT Output Low Voltage
I = 3mA
l
IOH
GPIO, ALERT Leakage Current
V = 33V
l
tPHL
Stress Condition to GPIO2 Low Propagation
Delay
GATE Low or VDS = 1V
l
5
13
35
µs
TIMER Low Threshold
Falling
l
0.11
0.15
0.19
V
TIMER High Threshold
Rising
l
1.25
1.28
1.31
V
TIMER Pull-Up Current
V = 0V
l
–18
–20
–22
µA
TIMER Pull-Down Current
V = 1.3V
l
3
5
7
µA
l
0.045
0.08
0.11
%
70
180
350
µA
TIMER Pin Functions
VTH
ITIMER
Doc
Overcurrent Auto-Retry Duty Cycle
SOURCE, ADC Pin Currents
ISOURCE
SOURCE Input Current
V = 12V
l
IADC–
ADC– Input Current
VADC– = 33V
l
0
±1
µA
IADC+
ADC+ Input Current
VADC+ = 33V
l
25
110
µA
ADC
12/16
Bits
RESOLUTION
ADC Resolution (No Missing Codes)
l
VOS
ADC Offset Error, Percent of Full-Scale
l
±0.25
%
TUE
ADC Total Unadjusted Error (Note 5)
∆VADC, SOURCE, VDD, GPIO
POWER
ENERGY (Internal Timebase)
ENERGY (Crystal/External Timebase)
l
l
l
l
±0.7
±1.0
±5.1
±1.0
%
%
%
%
FSE
ADC Full-Scale Error
∆VADC, SOURCE, VDD, GPIO
POWER
ENERGY (Internal Timebase)
ENERGY (Crystal/External Timebase)
l
l
l
l
±0.7
±1.0
±5.1
±1.0
%
%
%
%
VFS
ADC Full-Scale Range
∆VADC = ADC+ – ADC–
SOURCE/VDD = 24V Range
SOURCE/VDD = 12V Range
SOURCE/VDD = 5V Range
SOURCE/VDD = 3.3V Range
GPIO
INL
ADC Integral Nonlinearity, 12-Bit Mode
mV
V
V
V
V
V
40
33.28
16.64
8.32
5.547
1.28
l
0.2
±5
LSB
4281f
4
For more information www.linear.com/LTC4281
LTC4281
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VDD = 12V unless otherwise noted.
SYMBOL
PARAMETER
CONDITIONS
VFS
Alarm Threshold Full-Scale Range
(256 • VLSB)
∆VADC
SOURCE/VDD = 24V
SOURCE/VDD = 12V
SOURCE/VDD = 5V
SOURCE/VDD = 3.3V
GPIO
MIN
TYP
MAX
UNITS
RGPIO
GPIO ADC Sampling Resistance
V = 1.28V
l
1
2
fCONV
Conversion Rate
12-Bit Mode, Internal Clock
16-Bit Mode, Internal Clock
l
l
14.5
0.906
15.26
0.954
16
1
Hz
Hz
INTVCC
– 0.8
INTVCC
– 0.5
INTVCC
– 0.2
V
±3
µA
mV
V
V
V
V
V
40
33.28
16.64
8.32
5.547
1.28
MΩ
I2C Interface
VADR(H)
ADRn Input High Threshold
l
IADR(IN,Z)
ADRn Allowable Leakage in Open State
l
VADR(L)
ADRn Input Low Threshold
IADR(IN)
ADRn Input Current
VSDA,SCL(TH)
SDAI, SCL Input Threshold
ISDA,SCL(OH)
SDAI, SCL Input Current
SCL, SDA = 5.0V
l
VSDAO(OL)
SDAO, Output Low Voltage
I = 3mA
l
ISDAO(OH)
SDAO, Pin Input Leakage Current
VSDAO = 33V
l
l
ADR = 0V, ADR = INTVCC
0.2
0.5
l
l
1.5
1.7
0.8
V
±80
µA
2.0
V
±1
µA
0.3
0.4
V
0
±1
µA
I2C Interface Timing
fSCL(MAX)
Maximum SCL Clock Frequency
l
400
1000
kHz
0.12
1.3
µs
30
600
us
tBUF(MIN)
Bus Free Time Between STOP/START Condition
l
tHD,STA(MIN)
Hold Time After (Repeated) START Condition
l
tSU,STA(MIN)
Repeated START Condition Set-Up Time
l
30
600
ns
tSU,STO(MIN)
STOP Condition Set-Up Time
l
140
600
ns
tHD,DATI(MIN)
Data Hold Time (Input)
l
30
100
ns
tHD,DATO
Data Hold Time (Output)
l
tSU,DAT(MIN)
Data Set-Up Time
l
tSP(MAX)
Maximum Suppressed Spike Pulse Width
CX
SCL, SDA Input Capacitance
tD(STUCK)
I2C Stuck Bus Timeout
l
(Note 4)
300
50
500
900
ns
30
600
ns
110
250
ns
10
pF
35
ms
l
l
25
30
EEPROM Characteristics
Endurance
(Notes 7, 8)
l
10,000
Cycles
Retention
(Notes 7, 8)
l
20
Years
l
1
tWRITE
Write Operation Time
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All currents into pins are positive. All voltages are referenced to
GND unless otherwise specified.
Note 3: An internal clamp limits the GATE pin to a minimum of 11V above
SOURCE. Driving this pin to voltages beyond the clamp may damage the
device.
2.2
4
ms
Note 4: Guaranteed by design and not subject to test.
Note 5: TUE is the maximum ADC error for any code, given as a
percentage of full scale.
Note 6: UV, OV and FB internal thresholds are given as a percent
difference from the configured operating voltage.
Note 7: EEPROM endurance and retention are guaranteed by design,
characterization and correlation with statistical process controls.
Note 8: EEPROM endurance and retention will be degraded when TJ > 85°C.
4281f
For more information www.linear.com/LTC4281
5
LTC4281
Typical Performance Characteristics TA = 25°C, VDD = 12V unless otherwise noted.
Supply Current vs Voltage
3.3V Output Supply vs Voltage
4.50
3.5
3.50
4.25
3.3V Output Supply vs Load
Current for VDD = 12V
3.4
3.25
3.75
INTVCC (V)
INTVCC (V)
IDD (mA)
4.00
3.00
3.3
3.2
3.50
2.75
3.1
3.25
5
10
15
20
VDD (V)
25
30
2.50
2.50
35
25
25
20
20
POWER (W)
VSENSE (mV)
30
15
10
5
5
4
6
8
10
VOUT (V)
0
12
∆VGATE (V)
tPHL(GATE) (µs)
VDD = 12V
RSENSE = 1mΩ
0
2
4
6
8
10
20
40
60
VSENSE - VILIM (mV)
80
23
100
4281 G07
0
25
50
TEMPERATURE (°C)
75
100
External MOSFET Gate Drive
vs Leakage Current
13.0
12
10
12.6
12.0
–50
–25
4281 G06
14
12.2
0
24
13.2
1
VILIM = 25mV
20
4281 G03
25
4281 G05
12.4
0.1
16
26
22
–50
12
12.8
10
8
12
ILOAD (mA)
Current Limit Threshold
vs Temperature
External MOSFET Gate Drive
vs Temperature
FAST PULL–DOWN
4
27
4281 G04
1k
0
4281 G02
VOUT (V)
Current Limit Propagation Delay
vs Overdrive
100
3.0
5
15
10
2
4.50
MOSFET Power Limit
30
0
3.50
4
VDD (V)
4281 G01
Current Limit Foldback Profile
0
3
CIRCUIT BREAKER THRESHOLD (mV)
0
∆VGATE (V)
3.00
8
6
4
VDD = 12V
VDD = 5V
VDD = 3.3V
–25
0
25
50
TEMPERATURE (°C)
VDD = 12V
VDD = 5V
VDD = 3.3V
2
75
100
4281 G08
0
0
4
8
12
16
IGATE (LEAKAGE) (µA)
20
24
4281 G09
4281f
6
For more information www.linear.com/LTC4281
LTC4281
Typical Performance Characteristics
GPIO Pin Output Low Voltage
vs Load (VOL(GPIO) vs IGPIO)
–22
–20
1.0
0.000
0.8
–0.005
0.6
–0.010
ERROR (%)
VOL(GPIO) (V)
IGATE (µA)
–24
0.4
0.2
–18
–50
–25
0
25
50
TEMPERATURE (°C)
75
0
100
0
2
4
6
IGPIO (mA)
1.0
0.8
0.8
0.6
0.6
0.4
0.4
0.2
0.2
DNL (LSB)
INL (LSB)
1.0
–0.0
–0.2
–0.6
–0.6
–0.8
–0.8
2048
CODE
3072
–1.0
4096
Right Click In Graph Area for Menu
Double Click In Graph Area for Data Setup
1
1024
2048
CODE
3072
1000
0
–3
–2 –1
0
1
2
CODE VARIATION (LSB)
3
4
4281 G16
–0.05
–0.10
–25
0
25
50
TEMPERATURE (°C)
75
2000
0
VGPIO = 1.000V
RESOLUTION = 12b
VLSB = 312.5µV
6000
3000
100
12-Bit GPIO ADC Noise Histogram
7000
1000
–4
0.00
4281 G15
NUMBER OF READINGS
2000
ADC Full-Scale Error
vs Temperature (VFSE vs Temp.)
–0.20
–50
4095
∆VADC = 20mV
RESOLUTION = 16b
VLSB = 610nV
4000
3000
4095
4281 G12
16-Bit Current ADC Noise Histogram
5000
NUMBER OF READINGS
NUMBER OF READINGS
4000
3071
4281 G14
16-Bit GPIO ADC Noise Histogram
VIN = 1.000V
RESOLUTION = 16b
VLSB = 19.5µV
2048
CODE
–0.15
4281 G13
5000
1024
0.05
–0.2
–0.4
0
4281 G11
0.10
–0.0
–0.4
1024
–0.025
10
ADC Differential Non-Linearity
vs Code (DNL vs Code)
ADC Integral Non-Linearity
vs Code (INL vs Code)
0
8
–0.015
–0.020
85°C
25°C
–40°C
4281 G10
–1.0
ADC Total Unadjusted Error
vs Code (TUE vs Code)
FULL SCALE ERROR (%)
–26
External MOSFET Gate Drive
Current vs Temperature
(IGATE Current vs Temperature)
5000
4000
3000
2000
1000
–4
–3
–2 –1
0
1
2
CODE VARIATION (LSB)
3
4
4281 G17
0
–3
–2
–1
0
1
CODE VARIATION (LSB)
2
3
4281 G18
4281f
For more information www.linear.com/LTC4281
7
LTC4281
Pin Functions
ADC+: Positive Kelvin ADC Current Sense Input. Connect
this pin to the input side of the current sense resistor.
Must be connected to the same trace as VDD or a resistive
averaging network which adds up to 1Ω to VDD.
ADC–: Negative Kelvin ADC Current Sense Input. Connect
this pin to the output of the current sense resistor or a
resistive averaging network.
ADR0-ADR2: Serial Bus Address Inputs. Tying these pins
to ground (L), open (NC), or INTVCC (H) configures one
of 27 possible addresses. See Table 1 in the Applications
Information section.
ALERT: I2C Bus ALERT Output or General Purpose Input/
Output. Configurable to ALERT output, general purpose
output or logic input. Tie to ground if unused.
CLKIN: Clock Input. Connect to an optional external crystal
oscillator circuit or drive with an external clock. Tie to
ground if unused.
CLKOUT: Clock Output. Connect to an optional external
crystal oscillator circuit. Can be configured in non-volatile
memory to output the internal clock or a low pulse when
the ADC finishes a conversion. Float if unused.
FB: Foldback Current Limit and Power Good Input. A
resistive divider from the output is tied to this pin. When
the voltage at this pin drops below 1.28V, power is not
considered good. The power bad condition may result in the
GPIO1 pin pulling low or going high impedance depending
on the configuration of GPIO_CONFIG register 0x07 bits
4 and 5, also a power bad fault is logged in this condition
if the GATE pin is high. The start-up current limit folds
back to 30% as the FB pin voltage drops from 1.3V to 0V.
GATE: Gate Drive for External N-Channel MOSFET. An
internal 20µA current source charges the gate of the
MOSFET. No compensation capacitor is required on the
GATE pin, but a resistor and capacitor network from this
pin to ground may be used to set the output voltage slew
rate. During turn-off there is a 1mA pull-down current.
During a short-circuit or undervoltage lockout (VDD or
INTVCC), a 900mA pull-down between GATE and SOURCE
is activated.
GND: Device Ground.
GPIO1: General Purpose Input/Open-Drain Output. Configurable to general purpose output, logic input, and power
good or power bad signal. Tie to ground if unused.
GPIO2: General Purpose Input/Open-Drain Output. Configurable to general purpose output, logic input, MOSFET
stress output, or data converter input. Tie to ground if
unused.
GPIO3: General Purpose Input/ Open-Drain Output. Configurable to general purpose output, logic input, or data
converter input. Tie to ground if unused.
INTVCC: 3.3V Supply Decoupling Output. Connect a 1µF
capacitor from this pin to ground. To ensure fault logging
after power is lost a 4.7μF capacitor should be used. 25mA
may be drawn from this pin to power 3.3V application
circuitry. Increase capacitance by 1µF/mA external load
if fault logging is used. This pin should not be driven and
is not current limited.
ON: On Control Input. Used to monitor a connection sense
pin on the backplane connector. The default polarity is
high = on, but may be reconfigured to low = on by setting
CONTROL1 register 0x00 bit 5 low. A on-to-off transition
on this pin clears the fault register if CONTROL1 register
0x00 bit 7 is set high. The ON pin has a precise 1.28V
threshold, allowing it to double as a supply monitor.
OV: Overvoltage Input Pin. An overvoltage condition is
present when this pin is above the configured threshold.
Connect a resistive divider when the internal divider is
disabled, otherwise leave open.
SCL: Serial Bus Clock Input. Data at the SDA pin is shifted
in or out on rising edges of SCL. This is a high impedance
pin that is generally driven by an open-drain output from
a master controller. An external pull-up resistor or current
source is required.
SDAI: Serial Bus Data Input. A high impedance input for shifting in address, command or data bits.
Normally tied to SDAO to form the SDA line.
4281f
8
For more information www.linear.com/LTC4281
LTC4281
Pin Functions
SDAO: Serial Bus Data Output. Open-drain output for sending data back to the master controller or acknowledging a
write operation. Normally tied to SDAI to form the SDA line.
An external pull-up resistor or current source is required.
SENSE+: Positive Kelvin Current Sense Input. Connect
this pin to the input of the current sense resistor or an
averaging network in the case of multiple sense resistors.
The parallel resistance of an averaging network should not
exceed 1Ω. Must operate at the same potential as VDD.
SENSE–: Negative Kelvin Current Sense Input. Connect
this pin to the output of the current sense resistor. The
current limit circuit controls the GATE pin to limit the sense
voltage between the SENSE+ and SENSE– pins to the value
selected in the ILIM register or less.
SOURCE: N-Channel MOSFET Source and ADC Input. Connect to the source of the external N‑channel MOSFET. This
pin provides a return for the gate pull-down circuit and
also serves as the ADC input to monitor the output voltage.
TIMER: Current Limit and Retry Timer Input. Connect a
capacitor between this pin and ground to set a 64ms/µF
duration for current limit, after which an overcurrent fault
is logged and GATE is pulled low. The duration of the off
time is 73s/µF when overcurrent auto-retry is enabled,
resulting in a 0.08% duty cycle.
UV: Undervoltage Input. An undervoltage condition is present whenever this pin is below the configured threshold.
Connect a resistive divider when the internal divider is
disabled. A capacitor may be placed on this pin to filter
brief UV glitches on the input supply.
VDD: Supply Voltage Input and UV/OV Input. This pin has
an undervoltage lockout threshold of 2.7V. The UV and
OV thresholds are also measured at this pin, and the ADC
may be configured to read the voltage at this pin.
WP: EEPROM Write Protect. All writes to the EEPROM
except fault logging are blocked when WP is high.
4281f
For more information www.linear.com/LTC4281
9
LTC4281
Functional Diagram
24
25
SENSE–
SLOW CL
SOURCE
164k
25k
28k
10k
3.3V
1V
FB 0.3V
SENSE+
+
– –+
+–
25mV
5V
–
+
CHARGE
PUMP AND
GATE DRIVER
75mV
24V
+
–
GATE UP
ADJ
10k
21
1
+
–
1.280V
–5, 10, OR 15%
FB
ON
ON
1.280V
4
WP
WP
1.280V
31
VDD
SOURCE
164k
25k
28k
10k
10k
32
2
UV
+
–
GP
PG
GP
ON
LOGIC
+
–
+
–+ –
GP
FET BAD
UVLO2
200mV
3.3V
TM1
5V
12V
2.8V
24V
1.280V
5, 10,
OR 15%
OV
1.280V
5, 10, OR 15%
OSC
CLKIN
8
+
–
UVLO1
VDD(UVLO)
+
–
UV
+
–
OV
TM2
+
–
+
–
GPIO2
GPIO3
2.64V
VDD
20µA
INTVCC
5µA
GND
16
SDAO
GPIO3
12
12
SCL
SOURCE
16
MULT
+
–
ACC1
∆VSENSE
ADC+ ADC–
30
26
1
ACC2
POWER
48
ENERGY
32
TIME
5
3.3V
LDO
TIMER
A/D
CONVERTER 2
17
1.280V
+
–
MIN
MAX
LOG
18
1.280V
+
–
1.280V
19
1.280V
+
–
0.2V
A/D
CONVERTER 1
VDD
CLKOUT
7
21
8V
GPIO1
+
–
INTVCC
+–
SDAI
GPIO2
CLK
SOURCE
12
UV
OV
13.5V
22
FET ON
ILIM
ADJUST
12V
GATE
FAST CL
I2C
ALERT
6
3
12
13
14
15
ADR0
ADR1
ADR2
9
10
11
4281 BD
4281f
10
For more information www.linear.com/LTC4281
LTC4281
Operation
The LTC4281 is designed to turn a board’s supply voltage
on and off in a controlled manner, allowing the board to
be safely inserted or removed from a live backplane. During normal operation, the gate driver turns on an external
N-channel MOSFET to pass power to the load. The gate
driver uses a charge pump that derives its power from the
VDD pin. Also included in the gate driver is 12.5V GATEto-SOURCE clamp to protect the oxide of the external
MOSFET. During start-up the inrush current is tightly
controlled by using current limit foldback.
The current limit (CL) amplifier monitors the load current with a current sense resistor connected between the
SENSE+ and SENSE– pins. The CL amplifier limits the current in the load by pulling back on the GATE-to-SOURCE
voltage in an active control loop when the sense voltage
exceeds the commanded value.
An overcurrent fault at the output may result in excessive
MOSFET power dissipation during active current limiting.
To limit this power, the CL amplifier regulates the voltage
between the SENSE+ and SENSE– pins at the value set in
the ILIM register. When the output (SOURCE pin) is low,
power dissipation is further reduced by folding back the
current limit to 30% of nominal.
The TIMER pin ramps up with 20μA when the current
limit circuit is active. The LTC4281 turns off the GATE and
registers a fault when the TIMER pin reaches its 1.28V
threshold. At this point the TIMER pin ramps down using
a 5μA current source until the voltage drops below 0.2V
(comparator TM1). The TIMER pin will then ramp up and
down 256 times with 20µA/5µA before indicating that the
external MOSFET has cooled and it is safe to turn on again,
provided overcurrent auto-retry is enabled.
The output voltage is monitored using the SOURCE pin
and the power good (PG) comparator to determine if the
power is available for the load. The power good condition
can be signaled by the GPIO1 pin. The GPIO1 pin may also
be configured to signal power bad, as a general purpose
input (GP comparator), or a general purpose open-drain
output.
GPIO2 and GPIO3 may also be configured as general
purpose inputs or general purpose open-drain outputs.
Additionally, the ADC measures these pins with a 1.28V
full-scale. GPIO2 may be configured to pull low to indicate
that the external MOSFET is in a state of stress when the
MOSFET is commanded to be on and either the gate voltage is lower than it should be or the DRAIN-to-SOURCE
voltage exceeds 200mV.
The Functional Diagram shows the monitoring blocks of
the LTC4281. The group of comparators on the left side
includes the undervoltage (UV), overvoltage (OV), and
(ON) comparators. These comparators determine if the
external conditions are valid prior to turning on the GATE.
But first the two undervoltage lockout circuits, UVLO1
and UVLO2, validate the input supply and the internally
generated 3.3V supply, INTVCC. UVLO2 also generates
the power-up initialization to the logic circuits and copies
the contents of the EEPROM to operating memory after
INTVCC crosses this rising threshold.
Included in the LTC4281 is a pair of 12 to 16-bit A/D
converters. One data converter continuously monitors the
ADC+ to ADC– voltage, sampling every 16µs and producing
a 12-bit result of the average current sense voltage every
65ms. The other data converter is synchronized to the first
one and measures the GPIO voltage and SOURCE voltage
during the same time period. Every time the ADCs finish
taking a measurement, the current sense voltage is multiplied by the measurement of the SOURCE pin to provide
a power measurement. Every time power is measured, it
is added to an energy accumulator which keeps track of
how much energy has been transmitted to the load. The
energy accumulator can generate an optional alert upon
overflow, and can be preset to allow it to overflow after
a given amount of energy has been transmitted. A time
accumulator also keeps track of how many times the
power meter has been incremented; dividing the results
of the energy accumulator by the time accumulator gives
the average system power. The minimum and maximum
measurements of GPIO, SOURCE, ADC+ to ADC– and
POWER are stored, and optional alerts may be generated
if a measurement is above or below user configurable
8-bit thresholds.
An internal EEPROM provides nonvolatile configuration
of the LTC4281’s behavior, records fault information and
provides four bytes of uncommitted memory for general
purpose storage.
4281f
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11
LTC4281
Operation
An I2C interface is provided to read the A/D data registers.
It also allows the host to poll the device and determine
if faults have occurred. If the ALERT pin is configured
as an ALERT interrupt, the host is enabled to respond to
faults in real time. The I2C device address is decoded using the ADR0-ADR2 pins. These inputs have three states
each that decode into a total of 27 device addresses, as
shown in Table 1.
Applications Information
Turn-On Sequence
A typical LTC4281 application is a high availability system
in which a positive voltage supply is distributed to power
individual hot-swapped cards. The device measures card
voltages and currents and records past and present
fault conditions. The LTC4281 stores min and max ADC
measurements, calculates power and energy, and can
be configured to generate alerts based on measurement
results, avoiding the need for the system to poll the device on a regular basis. The LTC4281 is configured with
nonvolatile EEPROM memory, allowing it to be configured
during board level testing and avoid having to configure
the Hot Swap controller at every insertion.
The power supply on a board is controlled by using an
N-channel pass transistor, Q1, placed in the power path.
Resistor RS senses current through Q1. Resistors R1, R2
and R3 define undervoltage and overvoltage levels. R4
prevents high frequency self-oscillations in Q1, capacitors
C4 and C5 form a resonator network with crystal Y1 to
provide an accurate time base.
Several conditions must be present before the external
MOSFET turns on. First the external supply, VDD, must
exceed its 2.7V undervoltage lockout level. Next the
internally generated supply, INTVCC, must cross its 2.6V
undervoltage threshold. This generates a 1ms power-onreset pulse. During reset the fault registers are cleared and
the control registers are loaded with the data held in the
corresponding EEPROM registers.
A basic LTC4281 application circuit is shown in Figure 1.
The following sections cover turn-on, turn-off and various
faults that the LTC4281 detects and acts upon. External
component selection is discussed in detail in the Design
Example section.
RS
0.5mΩ
12V
Q1
PSMN2R0-30YLE × 2
CONNECTOR 1
CONNECTOR 2
R3
34.8k
1%
SDA
SCL
ALERT
CF
0.1µF
25V
Z1
SMCJI5C
×2
R2
1.18k
1%
R1
3.4k
1%
NC
12V
R4
10Ω
VDD ADC+ SENSE+
UV
OV
SDAI
SDAO
SCL
ALERT
ADR0
ADR1
ADR2
ON INTVCC
SENSE–
ADC–
GATE
CL
VOUT
12V
65A ADJUSTABLE
R8
3.57k
1%
SOURCE
GPIO1
GPIO2
GPIO3
LTC4281
TIMER
WP CLKIN
CLKOUT
POWER GOOD
GP
GP
GND
Y1
4MHz
C3
4.7µF
BACKPLANE PLUG-IN
CARD
+
FB
100k
GND
R7
30.1k
1%
CTIMER
15nF
C4
36pF
ABLS-4.000MHZ-B4-T
C5
36pF
4281 F01
Figure 1. Typical Application
4281f
12
For more information www.linear.com/LTC4281
LTC4281
Applications Information
After a power-on-reset pulse, the UV and OV pins verify
that input power is within the acceptable range. The state
of the UV and OV comparators is indicated by STATUS
register 0x1E bits 1 and 2 and must be stable for at least
50ms to qualify for turn-on. The ON pin is checked to see
that a connection sense (“short”) pin has asserted to the
correct state. By default the ON pin has no delay, but a
50ms debounce delay may be added by setting CONTROL
register 0x00 bit 6 high. When these conditions are satisfied, turn-on is initiated. Figure 4 shows connection sense
configurations for both high- and low-going short pins.
The ON pin has a precise 1.28V threshold, allowing it to
also monitor a voltage through the short pin, such as a
housekeeping or auxiliary supply delivered by the backplane. Use of the UV/OV divider for short pin detection in
high current applications is not recommended, as voltage
drops in the connector and fuse will impair the accuracy
of the intended function.
The MOSFET is then turned on by charging up the GATE
pin with a 20μA current source. When the GATE pin voltage reaches the MOSFET threshold voltage, the MOSFET
begins to turn on and the SOURCE voltage then follows
the GATE voltage as it increases.
While the MOSFET is turning on, the power dissipation in
the MOSFET is limited to a fixed value by the current limit
foldback profile as shown in Figure 2. As the SOURCE voltage rises, the FB pin follows as set by R7 and R8. Once
the GATE pin crosses its 8V ∆VGATE threshold and the FB
pin has exceeded its 1.28V threshold, the GPIO1 pin (in
its power good configuration) releases high to indicate
power is good and the load may be activated.
At the minimum input supply voltage of 2.9V, the minimum
GATE-to-SOURCE drive voltage is 10V. The GATE-toSOURCE voltage is clamped below 13.5V to protect the
gates of 20V N-channel MOSFETs. A curve of GATE-toSOURCE drive (∆VGATE) versus VDD is shown in the Typical
Performance Characteristics.
Turn-Off Sequence
A normal turn-off sequence is initiated by card withdrawal
when the backplane connector short pin opens, causing the
ON pin to change state. Turn-off may be also initiated by
writing a 0 to CONTROL register 0x00 bit 3. Additionally,
several fault conditions turn off the GATE pin. These include
an input overvoltage, input undervoltage, overcurrent or
VGATE
VDD + 12V
VDD + 8V
VDD
VOUT
POWER GOOD
(GPIO1)
VGS = 8V
VSENSE
100%
30%
NORMALIZED
MOSFET POWER
100%
ILOAD • RS
CURRENT
LIMITED
FB
LIMITED POWER
4281 F02
Figure 2. Power-Up Waveforms
4281f
For more information www.linear.com/LTC4281
13
LTC4281
Applications Information
FET-BAD fault. Setting high any of the UV, OV , OC or
FET-BAD fault bits (bits 0-2 and 6 of the FAULT_LOG
register 0x04, also latches off the GATE pin if the associated auto-retry bits are set low.
The MOSFET is turned off with a 1mA current pulling down
the GATE pin to ground. With the MOSFET turned off, the
SOURCE and FB voltages drop as the load capacitance discharges. When the FB voltage crosses below its threshold,
GPIO1 pulls low to indicate that the output power is no
longer good if configured to indicate power good. If the
VDD pin falls below 2.66V for greater than 2µs or INTVCC
drops below 2.49V for greater than 2µs, a fast shut down
of the MOSFET is initiated. The GATE pin is then pulled
down with a 900mA current to the SOURCE pin.
Current Limit Adjustment
The current limit sense voltage of the LTC4281 is adjustable
between 12.5mV and 34.4mV in 3.1mV steps via the I2C
interface with bits 7-5 of the ILIM_ADJUST register 0x11.
Default values are stored in the onboard EEPROM. This can
be used to adjust the sense voltage to achieve a given current
limit using the limited selection of standard sense resistor
values available around 1mΩ. It also allows the LTC4281
to reduce available current for light loads or increase it in
anticipation of a surge. This feature also enables the use
of board trace as a sense resistors by trimming the sense
voltage to match measured copper resistance during final
test. The measured copper resistance may be written to
the undedicated scratch pad area of the EEPROM so that
it is available to scale ADC current measurements.
loop is degraded by reducing the size of the resistor on
a gate RC network if one is used, which may necessitate
additional GATE-to-SOURCE capacitance. Board level
short-circuit testing is highly recommended as board
layout can also affect transient performance, the worstcase condition for current limit stability occurs when the
output is shorted to ground after a normal start-up.
Parasitic MOSFET Oscillations
Not all circuit oscillations can be ascribed to the current
limit loop. Some higher frequency oscillations can arise
from the MOSFET itself. There are two possible parasitic
oscillation mechanisms. The first type of oscillation occurs at high frequencies, typically above 1MHz. This high
frequency oscillation is easily damped with gate resistor
R4 as shown in Figure 1. In some applications, one may
find that this resistor helps in short-circuit transient recovery as well. However, too large of a resistor will slow
down the turn-off time. The recommended R4 range is
between 5Ω and 500Ω. 10Ω provides stability without
affecting turn-off time. This resistor must be located at the
MOSFET package with no other components connected
to the MOSFET gate pin.
A second type of parasitic oscillation occurs at frequencies
between 200kHz and 800kHz when the MOSFET source is
loaded with less than 10µF, and the drain is fed with an
inductive impedance such as contributed by wiring inductance. To prevent this second type of oscillation load the
source with more than 10µF and bypass the input supply
with a 10Ω, 100nF snubber to ground.
Current Limit Stability
Overcurrent Fault
For most applications the LTC4281 current limit loop is
stable without additional components. However there
are certain conditions where additional components may
be needed to improve stability. The dominant pole of the
current limit circuit is set by the capacitance at the gate of
the external MOSFET, and larger gate capacitance makes
the current limit loop more stable. Usually a total of 8nF
GATE-to-SOURCE capacitance is sufficient for stability and
is provided by inherent MOSFET CGS. The stability of the
The LTC4281 features an adjustable current limit with
foldback that protects the MOSFET from excessive load
current. To protect the MOSFET during active current
limit, the available current is reduced as a function of the
output voltage sensed by the FB pin such that the power
dissipated by the MOSFET is constant. A graph in the
Typical Performance Characteristics shows the current
limit and power versus FB voltage.
4281f
14
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LTC4281
Applications Information
An overcurrent fault occurs when the current limit circuitry
has been engaged for the MOSFET for longer than the
time-out delay set by the TIMER capacitor. Current limiting begins when the current sense voltage between the
SENSE+ and SENSE– pins reaches the current limit level
(which depends on foldback and the current limit configuration). The GATE pin is then pulled down and regulated in
order to limit the current sense voltage to the current limit
value. When the GATE pin regulator is in current limit, the
circuit breaker time delay starts by charging the external
timer capacitor from the TIMER pin with a 20µA pull-up
current. If the TIMER pin reaches its 1.28V threshold, the
external switch turns off with a 1mA current from GATE to
ground. If the GATE pin stops current limiting before the
TIMER pin reaches the 1.28V threshold, the TIMER pin
will discharge with 5μA. For a given circuit breaker time
delay, tCB, the equation for setting the timing capacitor’s
value is as follows:
CT = tCB • 0.016[μF/ms]
If an overcurrent fault is detected the MOSFET is turned off
and the TIMER pin begins discharging with a 5µA pull-down
current. When the TIMER pin reaches its 0.15V threshold,
it will cycle up and down with 20µA and 5µA 256 times to
allow the MOSFET time to cool down. When automatically
retrying, the resulting overcurrent duty cycle is 0.08%.
The final time the TIMER pin falls below its 0.15V lower
threshold the switches are allowed to turn on again if the
overcurrent auto-retry bit is set or the overcurrent fault
bit has been reset by the I2C interface.
The waveform in Figure 3 shows how the output turns off
following a short circuit.
Overvoltage Fault
An overvoltage fault occurs when the OV pin rises above
the OV threshold for longer than 15µs. This shuts off
the GATE pin with a 1mA current to ground and sets the
overvoltage present and overvoltage fault bits (Bit 0) in
STATUS and FAULT_LOG registers 0x1E and 0x04. If the
voltage subsequently falls back below the threshold for
50ms, the GATE pin is allowed to turn on again unless
overvoltage auto-retry has been disabled by clearing the
OV auto-retry bit (Bit 0) in CONTROL register 0x00. If an
external resistive divider is used, the OV threshold is 1.28V
on the OV pin. When using the internal dividers the OV
threshold is referenced to the VDD pin.
Undervoltage Fault
An undervoltage fault occurs when the UV pin falls below
its 1.28V threshold for longer than 15µs. This shuts off
the GATE pin with a 1mA current to ground and sets the
undervoltage present and undervoltage fault bits (Bit 0)
in STATUS and FAULT_LOG registers 0x1E and 0x04. If
GATE
10V/DIV
SOURCE
10V/DIV
TIMER EXPIRES
TIMER
2V/DIV
Current
50A/DIV
200µs/DIV
4281 F03
Figure 3. Short-Circuit Waveform
4281f
For more information www.linear.com/LTC4281
15
LTC4281
Applications Information
the voltage subsequently rises back above the threshold
for 50ms, the GATE pin is allowed to turn on again unless
undervoltage auto-retry has been disabled by clearing
the UV auto-retry bit in CONTROL register 0x00. For the
internal thresholds, the UV and OV signals may be filtered
by placing a capacitor on the UV pin.
12V
LTC4281
ON
CON
ON/OFF Control
The ON pin can be configured active high or active low with
CONTROL register 0x00 bit 5 (1 for active high). In the active
high configuration it is a true ON input, in the active low
configuration it can be used as an ENABLE input to detect
card insertion with a grounded short pin. The delay from
the ON pin commanding the part to turn on until the GATE
pin begins to rise is set by CONTROL registers 0x00 bit 6.
If this bit is low the GATE pin turns on immediately, and if it
is high it turns on after a 50ms debounce delay. Whenever
the ON pin toggles, bit 4 in FAULT_LOG register 0x04 is set
to indicate a change of state and the other bits in FAULT
register 0x04 are reset unless the ON_FAULT_MASK bit 7
in CONTROL register 0x00 is set.
The FET_ON bit, bit 3 of CONTROL register 0x00, is set
or reset by the rising and falling edges of the ON pin and
by I2C write commands. When the LTC4281 comes out of
UVLO the default state for bit 3 is read out of the EEPROM.
If it is a 0, the part is configured to stay off after power-up
and ignore the state of the ON pin. If it is a 1 the condition
of the ON pin will be latched to bit 3 after the debounce
period and the part will turn the GATE on if the ON pin is
in the ON state.
If the system shuts down due to a fault, it may be desirable
to restart the system simply by removing and reinserting
a load card. In cases where the LTC4281 and the switch
reside on a backplane or midplane and the load resides on
a plug-in card, the ON pin detects when the plug-in card is
removed. Figure 4 shows an example where the ON pin is
used to detect insertion. Once the plug-in card is reinserted
the FAULT_LOG register 0x04 is cleared (except for bit 5,
10k
4281 F04a
(a) ON Configured Active High (Default)
CONTROL Register 0x00 Bit 5=1
12V
CON
10k
LTC4281
ON
4281 F04b
(b) ON Configured Active Low CONTROL
Register 0x00 Bit 5=0
12V MAIN
LTC4281
AUX 3.3V
ON
13k
10k
CON
4281 F04c
(c) ON Pin Sensing of AUX Supply ON
Pin Configured Active High (Default)
Figure 4. Connection Sense Configurations with the ON Pin
4281f
16
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LTC4281
Applications Information
which indicates the ON pin changed state). After the ON
pin turn-on delay, the system is allowed to start up again.
If a connection sense on the plug-in card is driving the ON
pin, insertion or removal of the card may cause the pin
voltage to bounce. This results in clearing the FAULT_LOG
register when the card is removed. The pin may be debounced using a filter capacitor, CON, on the ON pin as
shown in Figure 4. Note that the polarity of the ON pin is
inverted with CONTROL Register 0x00 bit 5 set to 0.
FET-Bad Fault
In a Hot Swap application several things can prevent the
MOSFET from turning on and reaching a low impedance
state. A damaged MOSFET may have leakage from gate
to drain or have degraded RDS(ON). Debris on the board
may also produce leakage or a short from the GATE pin
to the SOURCE pin, the MOSFET drain, or to ground. In
these conditions the LTC4281 may not be able to pull the
GATE pin high enough to fully enhance the MOSFET, or
the MOSFET may not reach the intended RDS(ON) when
the GATE pin is fully enhanced. This can put the MOSFET
in a condition where the power in the MOSFET is higher
than its continuous power capability, even though the
current is below the current limit. The LTC4281 monitors
the integrity of the MOSFET in two ways, and acts on both
of them in the same manner.
First, the LTC4281 monitors the voltage between the
MOSFET VDD and SOURCE pins. The LTC4281 has a
comparator that detects a bad DRAIN-to-SOURCE voltage
(VDS) whenever the VDS is greater than 200mV.
Second, the LTC4281 monitors the GATE voltage. The GATE
voltage may not fully enhance with a damaged MOSFET,
and a severely damaged MOSFET most often has GATE,
DRAIN and SOURCE all shorted together. If the LTC4281
is in the ON state, but the GATE pin does not come up to
its 8V threshold above SOURCE, a FET-bad condition is
detected.
When either FET-bad condition is present while the
MOSFET is commanded on, an internal FET-bad fault
timer starts. When the timer reaches the threshold set in
FET_BAD_FAULT_TIME register 0x06 (1ms per LSB for a
maximum of 255ms), a FET-bad fault condition is set, the
part turns off, and the GATE pin is pulled low with a 1mA
current. In the case of a GAIN-to-DRAIN short, it may be
impossible for the LTC4281 to turn off the MOSFET. In
this case the LTC4281 can be configured to signal powerbad to the load so the load goes into a low current state
and send a FET-bad fault alert to the controller that may
be able to shut down upstream supplies and/or flag the
card for service.
The LTC4281 treats a FET-bad fault similar to an overcurrent
fault, and will auto-retry after 256 timer cycles if the
overcurrent auto-retry bit is set. Note that during startup, the FET-bad condition is present because the voltage
from DRAIN to SOURCE is greater than 200mV and the
GATE pin is not fully enhanced, thus the FET-bad timeout
must be long enough to allow for the largest allowable
load to start up. FET-bad faults are disabled by setting
the FET_BAD_FAULT_TIMER value to 0x00.
FET Short Fault
A FET short fault is reported if the data converter measures
a current sense voltage greater than or equal to 0.25mV
while the GATE pin is turned off. This condition sets the
FET_SHORT bit 5 in status register 0x1E, and FET_SHORT_
FAULT bit 5 in fault register 0x04.
Power-Bad Fault
The POWER_GOOD status bit, bit 3 in STATUS register
0x1E, is set when the FB pin voltage rises above its 1.28V
threshold. To indicate POWER_GOOD on the GPIO1 pin,
the GATE pin must first exceed the 8V VGS thresholds after
start-up, this requirement prevents POWER_GOOD from
asserting during start-up when the FB pin first crosses its
4281f
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17
LTC4281
Applications Information
GATE_HIGH
POWER_BAD_FAULT PRESENT
POWER_GOOD
STATUS
FET_ON
S
R
POWER_GOOD(GPIO)
Q
4281 F05
Figure 5. POWER_GOOD Logic
threshold. After start-up the GPIO1 pin will output the value
of the FB comparator so that POWER_GOOD stays high
even in cases such as an input voltage step that causes
the GATE pins to briefly dip below 8V VGS. See Figure 5.
A power bad fault is generated when the FB pin is low and
the GATE pin is high, preventing power-bad faults during
power-up or power-down.
Fault Alerts
A fault condition sets the corresponding fault bit in
FAULT_LOG register 0x04, ADC_ALERT_LOG register
0x05, and TIMER_OVERFLOW_PRESENT (Bit 1) and
METER_OVERFLOW_PRESENT (Bit 2) in the STATUS
register 0x1F. Fault bits are reset by writing a 0 and the
overflow status bits are reset by resetting the energy
meter by setting and resetting ADC_CONTROL register
0x1D bit 6. A fault condition can also generate an alert
(ALERT asserts low) by setting the corresponding bit in
the alert mask registers: ALERT registers 0x02 and 0x03,
and GPIO_CONFIG register bit 0. A low on ALERT may
be generated upon completion of an ADC measurement
by setting bit 2 in the GPIO_CONFIG register 0x07. This
condition does not have a corresponding fault bit. Faults
with enabled alerts set bit 7 in the ALERT_CONTROL
register 0x1C, which controls the state of the ALERT pin.
Clearing this bit will cause the ALERT pin to go high and
setting this bit causes it to go low. Alert masking stored
in EEPROM is transferred into registers at power up.
After the bus master controller broadcasts the Alert
Response Address, the LTC4281 responds with its address
on the SDA line and releases ALERT as shown in Figure 16.
If there is a collision between two LTC4281s responding
with their addresses simultaneously, then the device with
the lower address wins arbitration and releases its ALERT
pin. The devices that lost arbitration will still hold the
ALERT pin low and will respond with their addresses and
release ALERT as the I2C master broadcasts additional
Alert Response protocols until ALERT is release by all
devices. The ALERT pin can also be released by clearing
ALERT_CONTROL bit 7 in register 0x1C with the I2C
interface.
The ALERT pin can also be used as a GPIO pin, which
pulls low by setting ALERT_CONTROL bit 6 in register
0x1C. The ALERT pin input status is located in STATUS
register 0x1F bit 4.
Once the ALERT signal has been released from a fault, it
will pull low again if the corresponding fault reoccurs, but
not if the fault remains continuously present.
Resetting Faults in FAULT_LOG
The faults in FAULT_LOG register 0x04 may cause the
part to latch off if their corresponding auto-retry bits are
not set. In backplane resident applications it is desirable
to latch off if a card has produced a failure and start up
normally if the card is replaced. To allow this function the
ON pin must be used as a connection sense input. When
4281f
18
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LTC4281
Applications Information
CONTROL bit 7 in register 0x00 is not set, a turn-off signal
from the ON pin (card removed) will clear the FAULT_LOG
register except for bit 4 (ON changed state). The entire
FAULT_LOG register also cleared when the INTVCC pin
falls below it’s 2.49V threshold (UVLO), and individual
bits may be cleared manually via the I2C interface. Note
that faults that are still present, as indicated in STATUS
register 0x1E, cannot be cleared.
The FAULT_LOG register is not cleared when auto-retrying.
When auto-retry is disabled the existence of a logged fault
keeps the MOSFET off. As soon as the FAULT_LOG is
cleared, the MOSFET turns on. If auto-retry is enabled, then
a high status bit keeps the MOSFET off and the FAULT_LOG
bit is ignored. Subsequently, when the FAULT_LOG bit is
cleared by removal of the fault condition, the MOSFET is
allowed to turn on again even though the fault bit remains
set as a record of the previous fault condition.
Reboot
The LTC4281 features a reboot command bit, located in
bit 7 of ADC_CONTROL register 0x1D. Setting this bit will
cause the LTC4281 to reset and copy the contents of the
EEPROM to operating memory the same as after initial
power-up. The 50ms debounce before the part restarts
is lengthened to 3.2s for reboot in order to allow load
capacitance to discharge and reset before the LTC4281
turns back on. On systems where the Hot Swap controller
supplies power to the I2C master, this allows the master
to issue a command that power cycles the entire board,
including itself.
at the VDD pin or VOUT at the SOURCE pin by setting bit 3,
and can select between measuring GPIO2 or GPIO3 with
bit 2. The data converter full-scale is 40mV for the current
sense voltage, a choice of 33.28V, 16.64V, 8.32V or 5.547V
for VDD and VSOURCE, and 1.28V for GPIO.
The ADC+ and ADC– pins allow the ADC to measure the
voltage across the sense resistor. Some applications may
use two or more sense resistors in parallel to limit the
power in each resistor or achieve a specific parallel resistance or tolerance unavailable in a single sense resistor.
In this case averaging resistors can be used to accurately
measure the current by choosing averaging resistors with
the same ratio as the sense resistors they connect to. See
Figure 6. In this case the effective ADC sense resistor
is RS in parallel with k•RS for the current limit. Scaling
the averaging resistors, RA, by the same scaling factor,
k, allows the ADC to measure the correct sense voltage
for this effective sense resistor. The smallest averaging
resistor should not exceed 1Ω.
ADC+
SENSE+
RA
k •RA
RSENSE1
RS
RA
k •RA
ADC–
SENSE–
RSENSE2
k • RS
4281 F06
Figure 6. Weighted Averaging Sense Voltages
Data Converters
The LTC4281 incorporates a pair of sigma-delta A/D converters that are configurable to 12 or 16 bits. One converter
continuously samples the current sense voltage, while the
other monitors the input/output voltage and the voltage
on a GPIO input. The sigma-delta architecture inherently
averages signal noise during the measurement period.
The two data converters are synchronized, and after each
current measurement conversion, the measured current is
multiplied by the measured VDD or VSOURCE to yield input
or output power. After each conversion the measurement
results and power are compared to the recorded min and
max values. If the measurement is a new min or max, then
The data converters may be run in a 12-bit or 16-bit mode,
as selected by bit 1 in ILIM_ADJUST register 0x11. The
second data converter may be configured to measure VIN
4281f
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19
LTC4281
Applications Information
those registers are updated. The measurements are also
compared to the min/max alarm thresholds in registers
0x08 to 0x0F and will set the corresponding ADC alert bit
in ADC_ALERT_LOG register 0x05 and generate an alert
if configured to do so in ALERT register 0x03.
After each measurement, calculated power is added to
an accumulator that meters energy. Since the current is
continuously monitored by a dedicated ADC, the current
is sampled every 16µs, ensuring that the energy meter will
accurately meter noisy loads up to 62.5kHz noise frequency.
The 6-byte energy meter is capable of accumulating 20
days of power at full scale, which is several months at a
nominal power level. An optional alert may be generated
when the meter overflows. To measure coulombs, the
energy meter may be configured to accumulate current
rather than power by setting CLK_DIVIDER register 0x10
bit 7.
A time counter keeps track of how many times power has
been added into the energy meter. Dividing the energy by
the number in the counter will yield the average power
over the accumulated interval. When metering coulombs
dividing the metered charge by the counter produces the
average current over the accumulation interval. The 4-byte
time counter will keep count for 10 years in the 12-bit
mode before overflowing, and can generate an alert at
full scale to indicate that the counter is about to roll over.
Multiplying the value in the counter by tCONV yields the
time that the energy meter has been accumulating.
Both the energy accumulator and time counter are writable,
allowing them to be pre-loaded with a given energy and/
or time before overflow so that the LTC4281 will generate
an overflow alert after either a specified amount of energy
has been delivered or time has passed.
To calculate input/output voltage:
V=
CODE(word)• VFS(OUT)
216 −1
where VFS(OUT) is 33.28V, 16.64V, 8.32V or 5.547V depending on the part being in 24V, 12V, 5V or 3.3V mode,
respectively.
To calculate current in amperes:
I=
CODE(word)• 0.040V
(2 −1) •R
16
SENSE
To calculate power in watts:
P=
CODE(word)• 0.040V • VFS(OUT) • 216
(
)
2
216 −1 •RSENSE
To calculate energy in joules:
E=
CODE(48 bits)• 0.040V • VFS(OUT) • tCONV • 28
(2 −1)
16
2
•RSENSE
To calculate coulombs:
C=
CODE(48 Bits)• 0.040V • tCONV
(216 −1)•RSENSE
where tCON = (1/fCONV) is 0.065535s for 12-bit mode and
1.0486s for 16-bit mode.
To calculate average power over the energy accumulation
period:
P(AVG)=
E
tCONV •CODE(COUNTER)
The following formulas are used to convert the values in
the ADC result registers into physical units. The data in
the 12-bit mode is left justified, so the same equations
apply to the 12-bit mode and the 16-bit mode.
To calculate GPIO voltage:
To calculate GPIO voltage alarm thresholds:
V=
I(AVG)=
CODE(word)•1.280
16
2 −1
V=
C
tCONV •CODE(COUNTER)
CODE(byte)•1.280
255
4281f
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LTC4281
Applications Information
To calculate input/output voltage alarm thresholds:
VALARM =
CODE(byte)• VFS(OUT)
255
where VFS(OUT) is 33.28V, 16.64V, 8.32V or 5.5467V depending on the part being in 24V, 12V, 5V or 3.3V mode,
respectively.
To calculate current alarm thresholds in amperes:
CODE(byte)• 0.040V
I=
255 •RSENSE
To calculate power alarm threshold in watts:
P=
CODE(byte)• 0.040V • VFS(OUT) • 28
RSENSE • 255 • 255
Note that falling alarm thresholds use CODE(byte)+1 in
the above equations since they trip at the top edge of the
code, which is 1LSB higher than the rising threshold.
CLKIN, CLKOUT: Crystal Oscillator/External Clock
Accurately measuring energy by integrating power requires a precise integration period. The on-chip clock
of the LTC4281 is trimmed to 1.5% and specified over
temperature to 5% and is invoked by grounding CLKIN.
For increased accuracy a crystal oscillator or external precision clock may be used on the CLKIN and CLKOUT pins.
A 4MHz crystal oscillator or resonator may be connected
to the two CLK pins as shown in Figure 1.
Crystal oscillators are sensitive to noise and parasitic
capacitance. Care should be taken in layout to minimize
trace length between the LTC4281 and the crystal. Keep
noisy traces away from the crystal traces, or shield the
crystal traces with a ground trace.
Alternatively, an external clock may be applied to CLKIN
with CLKOUT left unconnected. The LTC4281 can accept an
external clock between 250kHz and 15.5MHz, with clocks
faster than 250kHz reduced to 250kHz by a programmable
divider, the clock frequency is divided by twice the value in
CLK_DIVIDER register 0x10 bits 0-4. Code 00000 passes
the clock through without division while code 01000 divides
a 4MHz clock down to 250kHz. The divided external clock
may differ from 250kHz by 5% without affecting other
specifications.
Configuring the GPIO Pins
The LTC4281 has three GPIO pins and an ALERT pin, all
of which can be used as general purpose input/output
pins. The GPIO1 pin is configured using the GPIO_CONFIG
register 0x07 bits 5-4. GPIO2 will pull low to indicate
MOSFET stress if GPIO_CONFIG bit 1 is set and pulls low
if bit 6 is low. GPIO3 pulls low if GPIO_CONFIG bit 7 is set
and is otherwise high impedance. The ALERT pin can be
used as a GPIO pin by setting all the alert enable bits to 0
to disable alerts, then setting bit 6 in ALERT_CONTROL
register 0x1C. Bit 7 in ALERT_CONTROL can also be set
to pull the ALERT pin low, but bit 7 will cause the part to
respond to the alert response protocol, while bit 6 will not.
GPIO1-GPIO3 and ALERT all have comparators monitoring
the voltage on these pins with a threshold of 1.28V when
the pins are serving as outputs. The results may be read
from the second byte of the STATUS register, 0x1F, bits 4-7.
Supply Transients
In card-resident applications, output short circuits working
against the inductive nature of the supply can easily cause
the input voltage to dip below the UV threshold.
In severe cases where the supply inductance is 500nH
or more, the input can dip below the VDD undervoltage
lockout threshold of 2.66V. Because the current passing
through the sense resistor changes no faster than a rate
of VSUPPLY/LSUPPLY, such as 12V/500nH = 24A/µs, it is
possible for the UV comparator and in particular, the VDD
UVLO circuit to respond before the current reaches the
current limit threshold. The VDD UVLO circuit responds
after a 2µs filter delay, pulling the GATE pin to SOURCE
with 900mA. Once the MOSFET turns off, VDD will return
4281f
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21
LTC4281
Applications Information
Supply Transient Protection
to its nominal voltage and the part initiates a new startup
sequence. The UV comparator responds after a 15µs
filter delay, making it less likely that this path will engage
before current limiting commences; adding a 100nF filter
capacitor to the UV pin ensures this. The fast current limit
amplifier engages at 3x the current limit threshold, and has
a propagation delay of 500ns. If the supply inductance is
less than 500nH in a 12V application, it is unlikely that the
VDD UVLO threshold will be breached and the fast di/dt
rate allows the current to rise to the 3x level long before
the UV pin responds.
The worst-case Z1 current is that which triggers the fast
current limit circuit. Several 1500W surge suppressors
may be required to clamp this current for high power
applications. Many 20V to 30V MOSFETs enter avalanche
breakdown before 45V. In those cases the MOSFET can act
as a surge suppressor and protect the Hot Swap controller
from inductive input voltage surges. In applications where
a high current ground is not available to connect the surge
suppressor, the surge suppressor may be connected
from input to output, allowing the output capacitance to
absorb spikes.
Once the fast current limit amplifier begins to arrest the
short-circuit current, the input voltage rapidly recovers
and even overshoots its DC value. The LTC4281 is safe
from damage up to 45V. To minimize spikes in backplaneresident applications, bypass the LTC4281 input supply
with an electrolytic capacitor between VDD and GND. In
card-resident applications clamp the VDD pin with a surge
suppressor Z1, as shown in Figure 7.
Design Example
As a design example, consider the following specifications:
VIN = 12V, IMAX = 50A, CL = 3300μF, VUV(ON) = 10.75V,
VOV(OFF) = 14.0V, VPWRGD(UP) = 11.6V, and I2C address
= 1010011, with overcurrent threshold set to 25mV. This
completed design is shown in Figure 7.
RS
0.5mΩ
12V
Q1
PSMN2R0-30YLE × 2
CONNECTOR 1
CONNECTOR 2
R3
34.8k
1%
SDA
SCL
ALERT
CF
0.1µF
25V
R1
3.4k
1%
Z1
SMCJ15CA
×2
12V
R2
1.18k
1%
NC
R4
10Ω
VDD ADC+ SENSE+
UV
OV
SDAI
SDAO
SCL
ALERT
ADR0
ADR1
ADR2
ON INTVCC
SENSE–
ADC–
GATE
CL
3300µF
R8
3.57k
1%
SOURCE
GPIO1
GPIO2
GPIO3
LTC4281
TIMER
WP CLKIN
CLKOUT
POWER GOOD
GP
GP
GND
Y1
4MHz
C3
4.7µF
BACKPLANE PLUG-IN
BOARD
+
FB
100k
GND
R7
30.1k
1%
VOUT
12V
50A
C4
36pF
CTIMER
47nF
ABLS-4.000MHZ-B4-T
C5
36pF
4281 F07
Figure 7. Design Example
4281f
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LTC4281
Applications Information
Selection of the sense resistor, RS, is set by the current
limit threshold of 25mV:
RS =
25mV
= 0.5mΩ
IMAX
For a start-up time of 1.33ms with a 2x safety margin we
choose:
The MOSFET is sized to handle the power dissipation during inrush when output capacitor COUT is being charged.
A method to determine power dissipation during inrush
is based on the principle that:
Energy in CL = Energy in Q1
where:
1
1
2
Energy in CL = CV 2 = (3.3mF ) (12) = 0.24J
2
2
During inrush, current limit foldback will limit the power
dissipation in the MOSFET to:
Energyin CL 0.24J
tSTARTUP =
=
=1.33ms
P
180W
DISS
The SOA (safe operating area) curves of candidate MOSFETs
must be evaluated to ensure that the heat capacity of the
package tolerates 180W for 1.33ms. The SOA curve of the
NXP PSMN2R0-30YLE shows 200W for 80ms, satisfying
this requirement. Additional MOSFETs in parallel may
be required to keep the MOSFET temperature or power
dissipation within limits at maximum load current. This
depends on board layout, airflow and efficiency requirements. To get the maximum DC dissipation below 2W per
MOSFET, a pair of PSMN2RO-30YLE is required for Q1.
Since the PSMN2R0-30YLE has 10nF of gate capacitance
it is likely to be stable, but the short-circuit stability of the
current limit should be checked and improved by adding
capacitors from GATE to SOURCE if needed.
tSTARTUP
1.33ms
=2•
≅ 47nF
64ms/µF
64ms/µF
In the event that the circuit attempts to start up into a
short circuit the current will be 30% of 50A, 15A, and the
voltage across the MOSFET will be 12V which the MOSFET will carry for 1.33ms. This is within the SOA of the
PSMN2R0-30YLE, so the application will safely survive
this fault condition.
The UV and OV resistor string values can be solved in the
following method. To keep the error due to 1µA of leakage to less than 1% choose a divider current of at least
200µA. R1 < 1.28V/200µA = 6.4kΩ. Then calculate the
following equations:
R2 =
7.5mV •12V
PDISS =
=180W
RS
Calculate the time it takes to charge up COUT:
CTIMER = 2 •
R3 =
VOV(OFF)
VUV(ON)
•R1•
UVTH(RISING)
OVTH(FALLING)
VUV(ON) • (R1+R2)
UVTH(RISING)
–R1
–R1–R2
In our case we choose R1 to be 3.4kΩ to give a resistor
string current greater than 200μA. Then solving the equations results in R2 = 1.18kΩ and R3 = 34.8kΩ.
The FB divider is solved by picking R8 and solving for R7,
choosing 3.57kΩ for R8 we get:
R7 =
VPWRGD(UP) •R8
FBTH(RISING)
–R8
Resulting in R7 = 30.1kΩ.
Since this application uses external resistive dividers
for UV, OV and FB, and the operating voltage is 12V, the
CONTROL register 0x01 is set to 0x02 to disable the internal thresholds and set the ADC to the 12V range. The
EEPROM CONTROL register 0x21 is also set to 0x02 so
the part will boot in the proper configuration.
4281f
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23
LTC4281
Applications Information
Since the start-up time is 1.33ms, the FET_BAD_FAULT_
TIME is set to 3ms for a ≥ 2x safety margin by writing
0x03 to the FET_BAD_FAULT_TIME register 0x06.
A 0.1μF capacitor, CF, is placed on the UV pin to prevent
supply glitches from turning off the GATE via UV or OV.
The address is set with the help of Table 1, which indicates
binary address 1010011 (0xA6). Address 0xA6 is set by
setting ADR2 high, ADR1 open and ADR0 high.
To improve noise immunity, put the resistive dividers to the
UV, OV and FB pins close to the device and keep traces to
VDD and GND short. It is also important to put the bypass
capacitor C3 as close as possible between INTVCC and GND.
A 0.1μF capacitor from the UV pin (and OV pin through
resistor R2) to GND also helps reject supply noise. Figure 8
shows a layout that addresses these issues. Note that
a surge suppressor, Z1, is placed between supply and
ground using wide traces.
Next the value of R4 is chosen to be the default value of
10Ω as discussed in the Current Limit Stability section.
A 4MHz crystal is placed between the CLKIN and CLKOUT
pins. The specified part requires 18pF load capacitance
which is provided by C4 and C5. To generate an internal
clock of 250kHz, 1000b is written to the CLOCK_DIVIDER
register 0x10 to divide the 4MHz crystal frequency by 16.
Since the fast pull-down is engaged at 150A, the input TVS
needs to be capable of clamping a 150A surge at a voltage
above the OV threshold but below the 45V absolute maximum rating of the LTC4281 for about 1µs. The SMCJ15CA
clamps 61.5A at 24V for 8.3ms, and can dissipate 30kW
for 1µs. One SMCJ15CA will meet these requirements.
In addition a 4.7μF ceramic bypass capacitor is placed
on the INTVCC pin. No bypass capacitor is required on
the VDD pin.
Layout Considerations
To achieve accurate current sensing, Kelvin connections
are required. The minimum trace width for 1oz copper
foil is 0.02" per amp to make sure the trace stays at a
reasonable temperature. Using 0.03" per amp or wider
is recommended. Note that 1oz copper exhibits a sheet
resistance of about 530μΩ/£. Small resistances add up
quickly in high current applications.
R1
Z1
R3
R2
CF
C3
CT
4281 F08
Figure 8. Recommended Layout
It is ill advised to place the ground plane under the power
MOSFETs. If they fail and overheat that could result in a
catastrophic failure as the input gets shorted to ground
when the insulation between them fails.
Digital Interface
The LTC4281 communicates with a bus master using a
2-wire interface compatible with I2C Bus and SMBus, an
I2C extension for low power devices. The LTC4281 is a
read-write slave device and supports SMBus Read Byte,
Write Byte, Read Word and Write Word commands, as
well as I2C continuous read and continuous write commands. Data formats for these commands are shown in
Figures 9 through 16.
4281f
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LTC4281
Applications Information
SDA
a6 – a0
SCL
1–7
b7 – b0
8
9
b7 – b0
1–7
8
9
1–7
8
9
S
START
CONDITION
P
ADDRESS
R/W
ACK
DATA
ACK
DATA
ACK
STOP
CONDITION
4281 F09
Figure 9. Data Transfer Over I2C or SMBus
S
ADDRESS
W
A COMMAND A
DATA
A
1 0 a4:a0
0
0
b7:b0
b7:b0
0
0
FROM MASTER TO SLAVE
P
4281 F10
A: ACKNOWLEDGE (LOW)
A: NOT ACKNOWLEDGE (HIGH)
R: READ BIT (HIGH)
W: WRITE BIT (LOW)
S: START CONDITION
P: STOP CONDITION
FROM SLAVE TO MASTER
Figure 10. LTC4281 Serial Bus SDA Write Byte Protocol
S
ADDRESS
W
A COMMAND A
DATA
A
DATA
A
1 0 a4:a0
0
0
b7:b0
b7:b0
0
b7:b0
0
0
P
4281 F11
Figure 11. LTC4281 Serial Bus SDA Write Word Protocol
S
ADDRESS
W
A COMMAND A
DATA
A
DATA
A
1 0 a4:a0
0
0
b7:b0
b7:b0
0
b7:b0
0
0
• • •
DATA
A
b7:b0
0
P
4281 F12
Figure 12. LTC4281 Serial Bus SDA Continuous Write Protocol
S
ADDRESS
W
A COMMAND A
1 0 a4:a0
0
0
b7:b0
0
S
ADDRESS
R
A
DATA
A
1 0 a4:a0
1
0
b7:b0
1
P
4281 F13
Figure 13. LTC4281 Serial Bus SDA Read Byte Protocol
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LTC4281
Applications Information
S
ADDRESS
W
A COMMAND A
1 0 a4:a0
0
0
b7:b0
S
0
ADDRESS
R
A
DATA
A
DATA
A
1 0 a4:a0
1
0
b7:b0
0
b7:b0
1
P
4281 F14
Figure 14. LTC4281 Serial Bus SDA Read Word Protocol
S
ADDRESS
W
A COMMAND A
1 0 a4:a0
0
0
b7:b0
0
S
ADDRESS
R
A
DATA
A
DATA
A
1 0 a4:a0
1
0
b7:b0
0
b7:b0
0
• • •
DATA
A
b7:b0
1
P
4281 F15
Figure 15. LTC4281 Serial Bus SDA Continuous Read Protocol
S
ALERT
RESPONSE
ADDRESS
R
A
DEVICE
ADDRESS
0001100
1
0
1 0 a4:a0 0 1
A
P
4281 F16
Figure 16. LTC4281 Serial Bus SDA Alert Response Protocol
START and STOP Conditions
When the bus is idle, both SCL and SDA are high. A bus
master signals the beginning of a transmission with a start
condition by transitioning SDA from high to low while
SCL is high, as shown in Figure 10. When the master has
finished communicating with the slave, it issues a STOP
condition by transitioning SDA from low to high while SCL
is high. The bus is then free for another transmission.
I2C Device Addressing
Twenty-seven distinct bus addresses are available using
three 3-state address pins, ADR0-ADR2. Table 1 shows the
correspondence between pin states and addresses. Note
that address bits 7 and 6 are internally configured to 10. In
addition, the LTC4281 responds to two special addresses.
Address 0xBE is a mass write address that writes to all
LTC4281s, regardless of their individual address settings.
Mass write can be disabled by setting bit 4 in CONTROL
register 0x00 to zero. Address (0x19) is the SMBus Alert
Response Address. If the LTC4281 is pulling low on the
ALERT pin, it acknowledges this address by broadcasting
its address and releasing the ALERT pin.
Acknowledge
The acknowledge signal is used in handshaking between
transmitter and receiver to indicate that the last byte of
data was received. The transmitter always releases the
SDA line during the acknowledge clock pulse. When the
slave is the receiver, it pulls down the SDA line so that it
remains LOW during this pulse to acknowledge receipt
of the data. If the slave fails to acknowledge by leaving
SDA high, then the master may abort the transmission by
generating a STOP condition. When the master is receiving
data from the slave, the master pulls down the SDA line
during the clock pulse to indicate receipt of the data. After
the last byte has been received the master leaves the SDA
line HIGH (not acknowledge) and issues a stop condition
to terminate the transmission.
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LTC4281
Applications Information
Write Protocol
The master begins communication with a START condition
followed by the seven bit slave address and the R/W bit set
to zero, as shown in Figure 12. The addressed LTC4281
acknowledges this and then the master sends a command
byte indicating which internal register the master wishes
to write. The LTC4281 acknowledges this and then latches
the command byte into its internal Register Address
pointer. The master then delivers the data byte and the
LTC4281 acknowledges once more and writes the data to
the destination register specified by the Register Address
pointer, then the pointer is incremented. If the Master
sends additional bytes, they are written sequentially to the
registers in order of their binary addresses. The transmission is ended when the master sends a STOP condition.
Read Protocol
The master begins a read operation with a START condition
followed by the seven bit slave address and the R/W bit set
to zero, as shown in Figure 15. The addressed LTC4281
acknowledges this and then the master sends a command
byte which indicates which internal register the master
wishes to read. The LTC4281 acknowledges this and then
latches the command byte into its internal Register Address pointer. The master then sends a repeated START
condition followed by the same seven bit address with the
R/W bit now set to one. The LTC4281 acknowledges and
sends the contents of the requested register. As long as
the master acknowledges the transmitted data byte the
internal register address pointer is incremented and the
next register byte is sent. The transmission is ended when
the master sends a STOP condition.
Data Synchronization
The ADC measurements and subsequent computed values
are 16-48 bits wide, but must be read over the I2C in 8-bit
segments. To ensure that the words are not updated in
the middle of reading them, the LTC4281 latches these
results while the I2C interface is busy. As long as the ADC
data is read out in a single transaction, all the data will
be synchronized. A STOP condition frees the LTC4281 to
update the ADC result registers. Status and fault registers
are updated in real time.
Alert Response Protocol
When any of the fault bits in FAULT_LOG register 0x04
are set, an optional bus alert is generated if the appropriate bit in the ALERT register 0x02 is also set. If an alert is
enabled, the corresponding fault causes the ALERT pin to
pull low. After the bus master controller broadcasts the
Alert Response Address, the LTC4281 responds with its
address on the SDA line and then releases ALERT when
it has successfully completed transmitting its address as
shown in Figure 16.
The ALERT signal is not pulled low again until the FAULT
register 0x04 indicates a different fault as occurred or
the original fault is cleared and it occurs again. Note that
this means repeated or continuing faults do not generate
alerts until the associated FAULT_LOG register bit has
been cleared.
EEPROM
The LTC4281 has an onboard EEPROM to allow nonvolatile
configuration and fault logging. The EEPROM registers are
denoted by ‘EE’ in the first column of register Table 2. The
EEPROM registers may be read and written like any other
register except that the EEPROM takes about 2ms to write
data. While the EEPROM is writing, the EEPROM_BUSY
bit, bit 2 in STATUS register 0x1F is set to 1. While the
EEPROM is busy the I2C interface will NACK commands
to read or write to EEPROM registers, but other registers
may be accessed during this time. When the EEPROM
finishes writing, the EEPROM_BUSY bit will reset and the
EEPROM_DONE bit, bit 7 in FAULT_LOG register 0x04 will
be set. If configured to generate an alert on EEPROM_DONE,
Bit 7 in ALERT register 0x02), the ALERT pin will pull low
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27
LTC4281
Applications Information
to alert the host that the EEPROM write has finished and
the LTC4281 EEPROM is ready to receive another byte.
When the LTC4281 comes out of UVLO or receives a
REBOOT command the contents of the EEPROM are
copied to the corresponding operating registers, which are
offset from the EEPROM register addresses by 0x20. The
SCRATCH_PAD registers, 0x4C-0x4F, are free for general
purpose use, such as storing fault history, serial numbers
or calibration data. The factory default EEPROM contents
make the LTC4281 behave similar to the LTC4215 to ease
design migration and provide a useful design starting point.
The FAULT_LOG and ADC_ALERT_LOG registers, 0x04 and
0x05, are not loaded from the EEPROM at boot. Instead the
register data is copied into the EEPROM when any of the
bits in the log registers transition high and fault logging is
enabled in ADC_CONTROL register 0x1D. Fault logging is
disabled by default after boot so that logged faults are not
inadvertently cleared by powering up with a fault condition
and overwriting the EEPROM. A 4.7µF capacitor on the
INTVCC pin allows the LTC4281 to operate and log faults
to the EEPROM if input power is lost. A 1uF capacitor may
be used in applications that do not require fault logging.
The WP pin prevents I2C writes to the EEPROM when
high. Attempts to write to the EEPROM while WP is high
will result in a NACK and no action. Usually the WP pin
is tied high through a resistor with a probe pad to allow
it to be pulled low manually, it may also be tied low to
enable writes all the time or connected to a GPIO pin or
other logic-level signal to allow software control of WP.
The EEPROM may still be read when WP is high. The
FAULT_LOG registers of the EEPROM will still log faults
when the WP pin is high. Linear Technology can provide
programmed parts that have WP locked in a high state to
make it impossible to change the default configuration by
any means. Please contact the factory.
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LTC4281
Applications Information
Table 1. LTC4281 Addressing
DESCRIPTION
DEVICE
ADDRESS*
0 = Write
1 = Read
BINARY DEVICE ADDRESS
LTC4281 ADDRESS PINS
h
7
6
5
4
3
2
1
0
ADR2
ADR1
ADR0
Mass Write
0xBE
1
0
1
1
1
1
1
0
X
X
X
Alert Response
0x19
0
0
0
1
1
0
0
1
X
X
X
0x80
1
0
0
0
0
0
0
X
L
NC
L
0x82
1
0
0
0
0
0
1
X
L
H
NC
0x84
1
0
0
0
0
1
0
X
L
NC
NC
0x86
1
0
0
0
0
1
1
X
L
NC
H
0x88
1
0
0
0
1
0
0
X
L
L
L
0x8A
1
0
0
0
1
0
1
X
L
H
H
0x8C
1
0
0
0
1
1
0
X
L
L
NC
0x8E
1
0
0
0
1
1
1
X
L
L
H
0x90
1
0
0
1
0
0
0
X
NC
NC
L
0x92
1
0
0
1
0
0
1
X
NC
H
NC
0x94
1
0
0
1
0
1
0
X
NC
NC
NC
0x96
1
0
0
1
0
1
1
X
NC
NC
H
0x98
1
0
0
1
1
0
0
X
NC
L
L
0x9A
1
0
0
1
1
0
1
X
NC
H
H
0x9C
1
0
0
1
1
1
0
X
NC
L
NC
0x9E
1
0
0
1
1
1
1
X
NC
L
H
0xA0
1
0
1
0
0
0
0
X
H
NC
L
0xA2
1
0
1
0
0
0
1
X
H
H
NC
0xA4
1
0
1
0
0
1
0
X
H
NC
NC
0xA6
1
0
1
0
0
1
1
X
H
NC
H
0xA8
1
0
1
0
1
0
0
X
H
L
L
0xAA
1
0
1
0
1
0
1
X
H
H
H
0xAC
1
0
1
0
1
1
0
X
H
L
NC
0xAE
1
0
1
0
1
1
1
X
H
L
H
0xB0
1
0
1
1
0
0
0
X
L
H
L
0xB2
1
0
1
1
0
0
1
X
NC
H
L
0xB4
1
0
1
1
0
1
0
X
H
H
L
* 8-bit hexadecimal address with LSB R/W bit = 0.
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29
LTC4281
Register Set
Table 2
REGISTER NAME
COMMAND BYTE
DESCRIPTION
READ/
WRITE
DATA
LENGTH
DEFAULT
CONTROL
0x00-0x01
Configures On/Off Behavior
RW
16 Bits
0xBB02
ALERT
0x02-0x03
Enables Alerts
RW
16 Bits
0x0000
FAULT_LOG
0x04
Logs Faults
RW
8 Bits
0x00
ADC_ALERT_LOG
0x05
Logs ADC Alerts
RW
8 Bits
0x00
FET_BAD_FAULT_TIME
0x06
Selects FET-BAD Fault Timeout
RW
8 Bits
0xFF
GPIO_CONFIG
0x07
Configures GPIO Outputs
RW
8 Bits
0x00
VGPIO_ALARM_MIN
0x08
Threshold For Min Alarm on VSOURCE
RW
8 Bits
0x00
VGPIO_ALARM_MAX
0x09
Threshold for Max Alarm on VSOURCE
RW
8 Bits
0xFF
VSOURCE_ALARM_MIN
0x0A
Threshold for Min Alarm on VGPIO
RW
8 Bits
0x00
VSOURCE_ALARM_MAX
0x0B
Threshold for Max Alarm on VGPIO
RW
8 Bits
0xFF
VSENSE_ALARM_MIN
0x0C
Threshold for Min Alarm on VSENSE
RW
8 Bits
0x00
VSENSE_ALARM_MAX
0x0D
Threshold for Max Alarm on VSENSE
RW
8 Bits
0xFF
POWER_ALARM_MIN
0x0E
Threshold for Min Alarm on POWER
RW
8 Bits
0x00
POWER_ALARM_MAX
0x0F
Threshold for Max Alarm on POWER
RW
8 Bits
0xFF
CLOCK_DIVIDER
0x10
Division Factor for External Clock
RW
8 Bits
0x08
ILIM_ADJUST
Adjusts Current Limit Value
RW
8 Bits
0x96
ENERGY
0x12-0x17
0x11
Meters Energy Delivered to Load
RW
48 Bits
0x000000
TIME_COUNTER
0x18-0x1B
Counts Power Delivery Time
RW
32 Bits
0x0000
ALERT_CONTROL
0x1C
Clear Alerts, Force ALERT Pin Low
RW
8 Bits
0x00
ADC_CONTROL
0x1D
Control ADC, Energy Meter
RW
8 Bits
0x00
STATUS
0x1E-0x1F
Fault and Pin Status
R
16 Bits
N/A
EE_CONTROL
0x20-0x21
EEPROM Default
RW
16 Bits
0xBB02
EE_ALERT
0x22-0x23
EEPROM Default
RW
16 Bits
0x0000
EE_FAULT
0x24
EEPROM Default
RW
8 Bits
0x00
EE_ADC_ALERT_LOG
0x25
EEPROM Default
RW
8 Bits
0x00
EE_FET_BAD_FAULT_TIME
0x26
EEPROM Default
RW
8 Bits
0xFF
EE_GPIO_CONFIG
0x27
EEPROM Default
RW
8 Bits
0x00
EE_VGPIO_ALARM_MIN
0x28
EEPROM Default
RW
8 Bits
0x00
EE_VGPIO_ALARM_MAX
0x29
EEPROM Default
RW
8 Bits
0xFF
EE_VSOURCE_ALARM_MIN
0x2A
EEPROM Default
RW
8 Bits
0x00
EE_VSOURCE_ALARM_MAX
0x2B
EEPROM Default
RW
8 Bits
0xFF
EE_VSENSE_ALARM_MIN
0x2C
EEPROM Default
RW
8 Bits
0x00
EE_VSENSE_ALARM_MAX
0x2D
EEPROM Default
RW
8 Bits
0xFF
EE_POWER_ALARM_MIN
0x2E
EEPROM Default
RW
8 Bits
0x00
EE_POWER_ALARM_MAX
0x2F
EEPROM Default
RW
8 Bits
0xFF
EE_CLOCK_DECIMATOR
0x30
EEPROM Default
RW
8 Bits
0x08
EE_ILIM_ADJUST
0x31
EEPROM Default
RW
8 Bits
0x96
Most Recent ADC Result for VGPIO
RW
16 Bits
N/A
VGPIO
0x34-0x35
VGPIO_MIN
0x36-0x37
Min ADC Result for VGPIO
RW
16 Bits
N/A
VGPIO_MAX
0x38-0x39
Max ADC Result for VGPIO
RW
16 Bits
N/A
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LTC4281
Register Set
Table 2
REGISTER NAME
COMMAND BYTE
DESCRIPTION
READ/
WRITE
DATA
LENGTH
DEFAULT
VSOURCE
0x3A-0x3B
Most Recent ADC Result for VSOURCE
RW
16 Bits
N/A
VSOURCE_MIN
0x3C-0x3D
Min ADC Result for VSOURCE
RW
16 Bits
N/A
VSOURCE_MAX
0x3E-0x3F
Max ADC Result for VSOURCE
RW
16 Bits
N/A
VSENSE
0x40-0x41
Most Recent ADC Result for VSENSE
RW
16 Bits
N/A
VSENSE_MIN
0x42-0x43
Min ADC Result for VSENSE
RW
16 Bits
N/A
VSENSE_MAX
0x44-0x45
Max ADC Result for VSENSE
RW
16 Bits
N/A
POWER
0x46-0x47
Most Recent ADC Result for POWER
RW
16 Bits
N/A
POWER_MIN
0x48-0x49
Min ADC Result for POWER
RW
16 Bits
N/A
POWER_MAX
0x4A-0x4B
Max ADC Result for POWER
RW
16 Bits
N/A
Spare EEPROM memory
RW
32 Bits
0x00000000
EE_SCRATCH
RESERVED
0x4C-0x4F
ALL OTHERS
Reserved for Future Expansion, Do Not Write
N/A
Detailed I2C Command Register Descriptions
CONTROL Registers (R/W)
Byte 1 (0x00)
BIT(S)
NAME
DEFAULT OPERATION
B[7]
ON_FAULT_MASK
1
If 1, blocks the ON pin from clearing the FAULT register to prevent repeated logged faults and
alerts.
B[6]
ON_DELAY
0
If 1, a 50ms debounce is applied to the ON pin commanding the part to turn on, if 0 the part turns
on immediately.
B[5]
ON/ENB
1
The ON pin is active high when this bit is a 1 and active low when this bit is a 0.
B[4]
MASS_WRITE_ENABLE
1
Writing a 1 enables MASS_WRITE to all LTC4281s on the I2C bus.
B[3]
FET_ON
1
Writing a 1 to this register turns the part on, writing a 0 turns off, overriding the ON pin.
B[2]
OC_AUTORETRY
0
Writing a 1 enables the part to auto-retry 256 timer cycles after an OC fault.
B[1]
UV_AUTORETRY
1
Writing a 1 enables the part to auto-retry 50ms after an UV fault.
B[0]
OV_AUTORETRY
1
Writing a 1 enables the part to auto-retry 50ms after an OV fault.
Byte 2 (0x01)
B[7-6]
FB_MODE
00
Selects threshold for POWER_GOOD, 00 = external, 01 = 5%, 10 = 10%, 11 = 15%.
B[5-4]
UV_MODE
00
Selects threshold for UV faults, 00 = external, 01 = 5%, 10 = 10%, 11 = 15%.
B[3-2]
OV_MODE
00
Selects threshold for OV faults, 00 = external, 01 = 5%, 10 = 10%, 11 = 15%.
B[1-0]
VIN_MODE
10
Selects operating range for UV/OV/FB and ADC: 00 = 3.3V, 01 = 5V, 10 = 12V, 11 = 24V.
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LTC4281
Detailed I2C Command Register Descriptions
ALERT Registers (R/W)
Byte 1 (0x02)
BIT(S)
NAME
DEFAULT OPERATION
B[7]
EEPROM_DONE_ALERT
0
Writing a 1 generates alerts when the EEPROM finishes writing.
B[6]
FET_BAD_FAULT_ALERT
0
Writing a 1 generates alerts when FET-BAD faults are produced.
B[5]
FET_SHORT_ALERT
0
Writing a 1 generates alerts when the ADC detects FET-short faults.
B[4]
ON_ALERT
0
Writing a 1 generates alerts when the ON pin changes state.
B[3]
PB_ALERT
0
Writing a 1 generates alerts when power-bad faults are produced.
B[2]
OC_ALERT
0
Writing a 1 generates alerts when overcurrent faults are produced.
B[1]
UV_ALERT
0
Writing a 1 generates alerts when undervoltage faults are produced.
B[0]
OV_ALERT
0
Writing a 1 generates alerts when overvoltage faults are produced.
POWER_ALARM_HIGH
0
Writing a 1 generates alerts when the ADC result is above the POWER_ALARM_MAX threshold.
Byte 2 (0x03)
B[7]
B[6]
POWER_ALARM_LOW
0
Writing a 1 generates alerts when the ADC result is below the POWER_ALARM_MIN threshold.
B[5]
VSENSE_ALARM_HIGH
0
Writing a 1 generates alerts when the ADC result is above the VSENSE_ALARM_MAX threshold.
B[4]
VSENSE_ALARM_LOW
0
Writing a 1 generates alerts when the ADC result is below the VSENSE_ALARM_MIN threshold.
B[3]
VSOURCE_ALARM_HIGH
0
Writing a 1 generates alerts when the ADC result is above the VSOURCE_ALARM_MAX threshold.
B[2]
VSOURCE_ALARM_LOW
0
Writing a 1 generates alerts when the ADC result is below the VSOURCE_ALARM_MIN threshold.
B[1]
VGPIO_ALARM_HIGH
0
Writing a 1 generates alerts when the ADC result is above the VGPIO_ALARM_MAX threshold.
B[0]
VGPIO_ALARM_LOW
0
Writing a 1 generates alerts when the ADC result is below the VGPIO_ALARM_MIN threshold.
FAULT_LOG Register (R/W)
Byte 1 (0x04)
BIT(S)
NAME
DEFAULT OPERATION
B[7]
EEPROM_DONE
0
Set to 1 when the EEPROM finishes a write.
B[6]
FET_BAD_FAULT
0
Set to 1 when a FET-BAD fault occurs.
B[5]
FET_SHORT_FAULT
0
Set to 1 when the ADC detects a FET-short fault.
B[4]
ON_FAULT
0
Set to 1 by the ON pin changing state.
B[3]
POWER_BAD_FAULT
0
Set to 1 by a power-bad fault occurring.
B[2]
OC_FAULT
0
Set to 1 by an overcurrent fault occurring.
B[1]
UV_FAULT
0
Set to 1 by an undervoltage fault occurring.
B[0]
OV_FAULT
0
Set to 1 by an overvoltage fault occurring.
ADC_ALERT_LOG Register (R/W)
Byte 1 (0x05)
BIT(S)
NAME
DEFAULT
OPERATION
B[7]
POWER_ALARM_HIGH
0
Set to 1when the ADC makes a measurement above the POWER_ALARM_MAX threshold.
B[6]
POWER_ALARM_LOW
0
Set to 1when the ADC makes a measurement below the POWER_ALARM_MIN threshold.
B[5]
VSENSE_ALARM_HIGH
0
Set to 1when the ADC makes a measurement above the VSENSE_ALARM_MAX threshold.
B[4]
VSENSE_ALARM_LOW
0
Set to 1when the ADC makes a measurement below the VSENSE_ALARM_MIN threshold.
B[3]
VSOURCE_ALARM_HIGH
0
Set to 1when the ADC makes a measurement above the VSOURCE_ALARM_MAX threshold.
B[2]
VSOURCE_ALARM_LOW
0
Set to 1when the ADC makes a measurement below the VSOURCE_ALARM_MIN threshold.
B[1]
GPIO_ALARM_HIGH
0
Set to 1when the ADC makes a measurement above the VGPIO_ALARM_MAX threshold.
B[0]
GPIO_ALARM_LOW
0
Set to 1when the ADC makes a measurement below the VGPIO_ALARM_MIN threshold.
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LTC4281
Detailed I2C Command Register Descriptions
FET_BAD_FAULT_TIME Register (R/W)
Byte 1 (0x06)
BIT(S)
NAME
B[7-0]
FET_BAD_FAULT_TIMEOUT
DEFAULT
255
OPERATION
Selects the wait time for a FET-bad fault as a binary integer in ms. 0x00 disables.
GPIO_CONFIG Register (R/W)
Byte 1 (0x07)
BIT(S)
NAME
DEFAULT
OPERATION
B[7]
GPIO3_PD
0
A 1 in this value will make the GPIO3 pin pull low, a 0 will make the pin high impedance
B[6]
GPIO2_PD
0
A 1 in this value will make the GPIO2 pin pull low, a 0 will make the pin high impedance
GPIO1_CONFIG
00
B[5-4]
FUNCTION
B[5]
B[4]
GPIO1 PIN
Power Good
0
0
GPIO1 = Power Good
Power Bad
1
0
GPIO1 = Power Bad
General Purpose Output
0
1
GPIO1 = B[3]
General Purpose Input
1
1
GPIO1 = High-Z
B[3]
GPIO1_OUTPUT
0
Output data bit to GPIO1 pin when configured as output (1 = high impedance, 0 = pull low)
B[2]
ADC_CONV_ALERT
0
Writing a 1 generates alert when the ADC finishes making a measurement
B[1]
STRESS_TO_GPIO2
0
Writing a 1 generates alert GPIO2 to pull low when the MOSFET is dissipating power (stress)
B[0]
METER_OVERFLOW_ALERT
0
Writing a 1 generates alert when the energy meter accumulator or time counter overflows
VGPIO_ALARM_MIN (Register R/W)
Byte 1 (0x08)
BIT(S)
NAME
B[7-0]
VGPIO_ALARM_MIN
DEFAULT OPERATION
0x00
Selects the maximum ADC measurement value that generates a VGPIO_MIN_ALARM
VGPIO_ALARM_MAX (Register R/W)
Byte 1 (0x09)
BIT(S)
NAME
B[7-0]
VGPIO_ALARM_MAX
DEFAULT OPERATION
0xFF
Selects the minimum ADC measurement value that generates a VGPIO_MAX_ALARM
VSOURCE_ALARM_MIN (Register R/W)
Byte 1 (0x0A)
BIT(S)
NAME
B[7-0]
VSOURCE_ALARM_MIN
DEFAULT
0x00
OPERATION
Selects the maximum ADC measurement value that generates a VSOURCE_MIN_ALARM
VSOURCE_ALARM_MAX (Register R/W)
Byte 1 (0x0B)
BIT(S)
NAME
B[7-0]
VSOURCE_ALARM_MAX
DEFAULT
0xFF
OPERATION
Selects the minimum ADC measurement value that generates a VSOURCE_MAX_ALARM
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LTC4281
Detailed I2C Command Register Descriptions
VSENSE_ALARM_MIN Register (R/W)
Byte 1 (0x0C)
BIT(S)
NAME
B[7-0]
VSENSE_ALARM_MIN
DEFAULT OPERATION
0x00
Selects the maximum ADC measurement value that generates a VSENSE_MIN_ALARM
VSENSE_ALARM_MAX (Register R/W)
Byte 1 (0x0D)
BIT(S)
NAME
B[7-0]
VSENSE_ALARM_MAX
DEFAULT OPERATION
0xFF
Selects the minimum ADC measurement value that generates a VSENSE_MAX_ALARM
POWER_ALARM_MIN (Register R/W)
Byte 1 (0x0E)
BIT(S)
NAME
B[7-0]
POWER_ALARM_MIN
DEFAULT OPERATION
0x00
Selects the maximum ADC measurement value that generates a POWER_MIN_ALARM
POWER_ALARM_MAX (Register R/W)
Byte 1 (0x0F)
BIT(S)
NAME
B[7-0]
POWER_ALARM_MAX
DEFAULT OPERATION
0xFF
Selects the minimum ADC measurement value that generates a POWER_MAX_ALARM
CLOCK_DIVIDER (Register R/W)
Byte 1 (0x10)
BIT(S)
NAME
DEFAULT OPERATION
B[7]
COULOMB_METER
0
Setting this bit to a 1 configures the Energy meter to accumulate current instead of power,
making it a Coulomb meter
B[6]
TICK_OUT
0
Configures the CLKOUT pin to output the internal time count (conversion time) as an open-drain
output
B[5]
INT_CLK_OUT
0
Configures the CLKOUT pin to output the internal system clock as an open-drain output
B[4-0]
CLOCK_DIVIDER
01000
The clock frequency input on the CLKIN pin gets divided by twice this integer to produce the
system clock at the target frequency of 250kHz. Code 00000 passes the clock without division.
4281f
34
For more information www.linear.com/LTC4281
LTC4281
Detailed I2C Command Register Descriptions
ILIM_ADJUST Register (R/W)
Byte 1 (0x11)
BIT(s)
NAME
B[7-5]
ILIM_ADJUST
Default
100
Operation
Selects the current limit values [mV]
B[7]
0
0
0
0
1
1
1
1
B[4-3]
B[2]
B[6]
0
0
1
1
0
0
1
1
B[5]
0
1
0
1
0
1
0
1
FB = LOW
3.75
4.6875
5.625
6.5625
7.5
8.4375
9.375
10.3125
FB = HIGH
12.5
15.625
18.75
21.875
25
28.125
31.25
34.375
FAST COMPARATOR
38
47
56
66
75
84
94
103
FOLDBACK_MODE
10
Selects the voltage range for the current limit foldback profile: 00 = 3.3V, 01 = 5V, 10 = 12V,
11 = 24V
VSOURCE/VDD
1
Setting this bit to a 1 makes the ADC monitor the SOURCE voltage, 0 for VDD
B[1]
GPIO_MODE
1
Setting this bit to a 1 makes the ADC monitor GPIO2, 0 for GPIO3
B[0]
16_BIT
0
Setting this bit to a 1 will make the ADC operate in 16-bit mode, 0 will make the ADC operate in
12-bit mode
ENERGY REGISTER (R/W)
Byte 1-6 (0x12-0x17)
BIT(S)
NAME
DEFAULT OPERATION
B[48-0]
ENERGY_METER
0x000000 Metered energy value
TIME_COUNTER REGISTER (R/W)
Byte 1-4 (0x18-0x1B)
BIT(S)
NAME
B[32-0]
TIME_COUNTER
DEFAULT OPERATION
0x0000
Counts the number of conversion cycles that power measurements have been accumulated in
the energy meter
ALERT_CONTROL REGISTER (R/W)
Byte 1 (0x1C)
BIT(S)
NAME
B[7]
ALERT_GENERATED
B[6]
B[5-0]
DEFAULT OPERATION
0
This bit is set to 1 when an alert is generated. It must be manually cleared by writing a 0 to it via
I2C. This bit can be set via I2C to simulate an alert
ALERT_PD
0
When this bit is set to 1 the ALERT pin pulls low as a general purpose output low
RESERVED
000000
Always read as 0
4281f
For more information www.linear.com/LTC4281
35
LTC4281
Detailed I2C Command Register Descriptions
ADC_CONTROL Register (R/W)
Byte 1 (0x1D)
BIT(S)
NAME
DEFAULT
OPERATION
B[7]
REBOOT
0
Writing a 1 to this bit will cause the LTC4281 to turn off and reboot to the EEPROM default
configuration and restart, if configured to do so, after 3.2s.
B[6]
METER_RESET
0
Writing a 1 to this bit resets the energy meter accumulator and time counter and holds them
reset until this bit is cleared.
B[5]
METER_HALT
0
Writing a 1 to this bit stops the energy meter and time counter.
RESERVED
00
Always read as 0.
B[2]
FAULT_LOG_ENABLE
0
Setting this bit to 1 enables registers 0x04 and 0x05 to be written to the EEPROM when a fault
bit transitions high.
B[1]
GATELOW
B[0]
ADC_HALT
B[4-3]
GATELOW Gives the status of the GATE pin 0 if the GATE pin is higher than 8V (Read Only)
0
Single shot mode, writing to this register again with HALT = 1 will allow the ADCs to make a
single conversion and then stop, clearing this bit allows the ADCs to run continuously
STATUS Register (R)
Byte 1 (0x1E)
BIT(S)
NAME
OPERATION
B[7]
ON_STATUS
A 1 indicates if the MOSFETs are commanded to turn on
B[6]
FET_BAD_COOLDOWN_STATUS
A 1 indicates that an FET-BAD fault has occurred and the part is going through a
cool-down cycle
B[5]
FET_SHORT_PRESENT
A 1 indicates that the ADCs have detected a shorted MOSFET
B[4]
ON_PIN_STATUS
A 1 indicates the status of the ON pin, 1 = high
B[3]
POWER_GOOD_STATUS
A 1 indicates if the output voltage is greater than the power good threshold
B[2]
OC_COOLDOWN_STATUS
A 1 indicates that an overcurrent fault has occurred and the part is going through a
cool-down cycle.
B[1]
UV_STATUS
A 1 indicates that the input voltage is below the undervoltage threshold
B[0]
OV_STATUS
A 1 indicates that the input voltage is above the overvoltage threshold
Byte 2 (0x1F)
B[7]
GPIO3_STATUS
A 1 indicates that the GPIO3 pin is above its input threshold
B[6]
GPIO2_STATUS
A 1 indicates that the GPIO2 pin is above its input threshold
B[5]
GPIO1_STATUS
A 1 indicates that the GPIO1 pin is above its input threshold
B[4]
ALERT_STATUS
A 1 indicates that the ALERT pin is above its input threshold
B[3]
EEPROM_BUSY
This bit is high whenever the EEPROM is writing, and indicates that the EEPROM is not available
until the write is complete
B[2]
ADC_IDLE
This bit indicates that the ADC is idle. It is always read as 0 when the ADCs are free running, and
will read a 1 when the ADC is idle in single shot mode
B[1]
TICKER_OVERFLOW_PRESENT
A 1 indicates that the tick counter has overflowed
B[0]
METER_OVERFLOW_PRESENT
A 1 indicates that the energy meter accumulator has overflowed
4281f
36
For more information www.linear.com/LTC4281
LTC4281
Detailed I2C Command Register Descriptions
EE_CONTROL Non-Volatile Register (R/W)
Byte 1 (0x20)
BIT(S)
NAME
B[7-4]
Same as CONTROL 0x00
DEFAULT
10111
OPERATION
B[3]
Same as CONTROL 0x00
1
B[2-0]
Same as CONTROL 0x00
011
Sets the default auto-retry behavior
Same as CONTROL 0x01
0x02
Stores default state for CONTROL byte 2 (0x01) in nonvolatile memory
Stores default state for CONTROL byte 1 (0x00) in nonvolatile memory
Sets the default ON state. 0 = OFF, 1 = ON-pin state.
Byte 2 (0x21)
B[7-0]
EE_ALERT Non-Volatile Register (R/W)
Byte 1 (0x22)
BIT(S)
NAME
DEFAULT
OPERATION
B[7-0]
Same as ALERT 0x02
0x00
Stores default state for ALERT byte 1 (0x02) in nonvolatile memory
Same as ALERT 0x03
0x00
Stores default state for ALERT byte 2 (0x03) in nonvolatile memory
Byte 2 (0x23)
B[7-0]
EE_FAULT_LOG Non-Volatile Register (R/W)
Byte 1 (0x24)
BIT(S)
NAME
B[7-0]
Same as FAULT_LOG
DEFAULT
OPERATION
0x00
When a new fault occurs, the contents of FAULT_LOG register (0x04) are copied to this
nonvolatile memory location
EE_ADC_ALERT_LOG Non-Volatile Register (R/W)
Byte 1 (0x25)
BIT(S)
NAME
B[7-0]
Same as ADC_ALERT_LOG
DEFAULT
OPERATION
0x00
When a new ADC Alert is generated, the contents of ADC_ALERT_LOG register (0x05) are
copied to this nonvolatile memory location
EE_FET_BAD_FAULT_TIME Non-Volatile Register (R/W)
Byte 1 (0x26)
BIT(S)
NAME
B[7-0]
Same as FET_BAD_FAULT_TIME
DEFAULT
0xFF
OPERATION
Stores default state for the FET_BAD_FAULT_TIME register (0x06) in nonvolatile memory
EE_GPIO_CONFIG Non-Volatile Register (R/W)
Byte 1 (0x27)
BIT(S)
NAME
B[7-0]
Same as GPIO_CONFIG
DEFAULT
0x00
OPERATION
Stores default state for GPIO_CONFIG register (0x07) in nonvolatile memory
EE_VGPIO_ALARM_MIN Non-Volatile Register (R/W)
Byte 1 (0x28)
BIT(S)
NAME
B[7-0]
VGPIO_ALARM_MIN
DEFAULT
0x00
OPERATION
Stores default state for VGPIO_ALARM_MIN register (0x08) in nonvolatile memory
4281f
For more information www.linear.com/LTC4281
37
LTC4281
Detailed I2C Command Register Descriptions
EE_VGPIO_ALARM_MAX Non-Volatile Register (R/W)
Byte 1 (0x29)
BIT(s)
NAME
B[7-0]
VGPIO_ALARM_MAX
Default
Operation
0xFF
Stores default state for VGPIO_ALARM_MAX register (0x09) in nonvolatile memory
EE_VSOURCE_ALARM_MIN Non-Volatile Register (R/W)
Byte 1 (0x2A)
BIT(s)
NAME
B[7-0]
VSOURCE_ALARM_MIN
Default
Operation
0x00
Stores default state for VSOURCE_ALARM_MIN register (0x0A) in nonvolatile memory
EE_VSOURCE_ALARM_MAX Non-Volatile Register (R/W)
Byte 1 (0x2B)
BIT(s)
NAME
B[7-0]
VSOURCE_ALARM_MAX
Default
Operation
0xFF
Stores default state for VSOURCE_ALARM_MAX register (0x0B) in nonvolatile memory
EE_VSENSE_ALARM_MIN Non-Volatile Register (R/W)
Byte 1 (0x2C)
BIT(S)
NAME
B[7-0]
VSENSE_ALARM_MIN
DEFAULT
0x00
OPERATION
Stores default state for VSENSE_ALARM_MIN register (0x0C) in nonvolatile memory
EE_VSENSE_ALARM_MAX Non-Volatile Register (R/W)
Byte 1 (0x2D)
BIT(S)
NAME
B[7-0]
VSENSE_ALARM_MAX
DEFAULT
0xFF
OPERATION
Stores default state for VSENSE_ALARM_MAX register (0x0D) in nonvolatile memory
EE_POWER_ALARM_MIN Non-Volatile Register (R/W)
Byte 1 (0x2E)
BIT(S)
NAME
B[7-0]
POWER_ALARM_MIN
DEFAULT
0x00
OPERATION
Stores default state for POWER_ALARM_MIN register (0x0E) in nonvolatile memory
EE_POWER_ALARM_MAX Non-Volatile Register (R/W)
Byte 1 (0x2F)
BIT(S)
NAME
B[7-0]
POWER_ALARM_MAX
DEFAULT
0xFF
OPERATION
Stores default state for POWER_ALARM_MAX register (0x0F) in nonvolatile memory
EE_CLOCK_DIVIDER Non-Volatile Register (R/W)
Byte 1 (0x30)
BIT(S)
NAME
B[7-0]
Same as CLOCK_DIVIDER
DEFAULT
0x08
OPERATION
Stores default state for CLOCK_DIVIDER register (0x10) in nonvolatile memory
4281f
38
For more information www.linear.com/LTC4281
LTC4281
Detailed I2C Command Register Descriptions
EE_ILIM_ADJUST Non-Volatile Register (R/W)
Byte 1 (0x31)
BIT(S)
NAME
B[7-0]
Same as ILIM_ADJUST
DEFAULT
0x96
OPERATION
Stores default state for ILIM_ADJUST register (0x11) in nonvolatile memory
Reserved
Byte 1 (0x32)
BIT(S)
NAME
OPERATION
B[7-0]
Reserved
Always read as 0x00
Reserved
Always read as 0x00
BIT(S)
NAME
OPERATION
B[7-0]
VGPIO_MSB
Stores the MSBs for the most recent VGPIO measurement result
VGPIO_LSB
Stores the LSBs for the most recent VGPIO measurement result
BIT(S)
NAME
OPERATION
B[7-0]
VGPIO_MIN_MSB
Stores the MSBs for the smallest VGPIO measurement result
VGPIO_MIN_LSB
Stores the LSBs for the smallest VGPIO measurement result
BIT(S)
NAME
OPERATION
B[7-0]
VGPIO_MAX_MSB
Stores the MSBs for the largest VGPIO measurement result
VGPIO_MAX_LSB
Stores the LSBs for the largest VGPIO measurement result
BIT(S)
NAME
OPERATION
B[7-0]
VSOURCE_MAX_MSB
Stores the MSBs for the most recent VSOURCE measurement result
VSOURCE_MAX_LSB
Stores the LSBs for the most recent VSOURCE measurement result
Byte 2 (0x33)
B[7-0]
VGPIO
Byte 1 (0x34)
Byte 2 (0x35)
B[7-0]
VGPIO_MIN
Byte 1 (0x36)
Byte 2 (0x37)
B[7-0]
VGPIO_MAX
Byte 1 (0x38)
Byte 2 (0x39)
B[7-0]
VSOURCE
Byte 1 (0x3A)
Byte 2 (0x3B)
B[7-0]
4281f
For more information www.linear.com/LTC4281
39
LTC4281
Detailed I2C Command Register Descriptions
VSOURCE_MIN Register (R/W)
Byte 1 (0x3C)
BIT(S)
NAME
OPERATION
B[7-0]
VSOURCE_MIN_MSB
Stores the MSBs for the smallest VSOURCE measurement result
VSOURCE_MIN_LSB
Stores the LSBs for the smallest VSOURCE measurement result
Byte 2 (0x3D)
B[7-0]
VSOURCE_MAX Register (R/W)
Byte 1 (0x3E)
BIT(S)
NAME
OPERATION
B[7-0]
VSOURCE_MAX_MSB
Stores the MSBs for the largest VSOURCE measurement result
VSOURCE_MAX_LSB
Stores the LSBs for the largest VSOURCE measurement result
Byte 2 (0x3F)
B[7-0]
VSENSE Register (R/W)
Byte 1 (0x40)
BIT(S)
NAME
OPERATION
B[7-0]
VSENSE_MSB
Stores the MSBs for the most recent VSENSE measurement result
VSENSE_LSB
Stores the LSBs for the most recent VSENSE measurement result
Byte 2 (0x41)
B[7-0]
VSENSE_MIN Register (R/W)
Byte 1 (0x42)
BIT(S)
NAME
OPERATION
B[7-0]
VSENSE_MIN_MSB
Stores the MSBs for the smallest VSENSE measurement result
VSENSE_MIN_LSB
Stores the LSBs for the smallest VSENSE measurement result
Byte 2 (0x43)
B[7-0]
VSENSE_MAX Register (R/W)
Byte 1 (0x44)
BIT(S)
NAME
OPERATION
B[7-0]
VSENSE_MAX_MSB
Stores the MSBs for the largest VSENSE measurement result
VSENSE_MAX_LSB
Stores the LSBs for the largest VSENSE measurement result
Byte 2 (0x45)
B[7-0]
POWER Register (R/W)
Byte 1 (0x46)
BIT(S)
NAME
OPERATION
B[7-0]
POWER_MSB
Stores the MSBs for the most recent POWER measurement result
POWER_LSB
Stores the LSBs for the most recent POWER measurement result
Byte 2 (0x47)
B[7-0]
4281f
40
For more information www.linear.com/LTC4281
LTC4281
Detailed I2C Command Register Descriptions
POWER_MIN Register (R/W)
Byte 1 (0x48)
BIT(S)
NAME
OPERATION
B[7-0]
POWER_MIN_MSB
Stores the MSBs for the smallest POWER measurement result
POWER_MIN_LSB
Stores the LSBs for the smallest POWER measurement result
Byte 2 (0x49)
B[7-0]
POWER_MAX Register (R/W)
Byte 1 (0x4A)
BIT(S)
NAME
OPERATION
B[7-0]
POWER_MAX_MSB
Stores the MSBs for the largest POWER measurement result
POWER_MAX_LSB
Stores the LSBs for the largest POWER measurement result
Byte 2 (0x4B)
B[7-0]
SCRATCH_PAD Non-Volatile Register (R/W)
Byte 1 (0x4C)
BIT(S)
NAME
DEFAULT
OPERATION
B[7-0]
SCRATCH_PAD_1
0x00
Uncommitted nonvolatile memory
SCRATCH_PAD_2
0x00
Uncommitted nonvolatile memory
SCRATCH_PAD_3
0x00
Uncommitted nonvolatile memory
SCRATCH_PAD_4
0x00
Uncommitted nonvolatile memory
Byte 2 (0x4D)
B[7-0]
Byte 3 (0x4E)
B[7-0]
Byte 4 (0x4F)
B[7-0]
4281f
For more information www.linear.com/LTC4281
41
LTC4281
Typical Applications
12V, 50A Backplane Resident Application
RS
0.5mΩ
Q2
PSMN2R0-30YLE × 2
CF
0.1µF
25V
+
CS
150µF
R2
1.18k
1%
R3
3.4k
1%
R7
30.1k
1%
R4
10Ω
VDD ADC+
SENSE1+ SENSE1–
ADC–
GATE
SOURCE
UV
OV
LTC4281
NC
ADR0
ADR1
ADR2
INTVCC
TIMER
WP
CLKIN
R8
3.57k
1%
CLKOUT
FB
GPIO1
GPIO2
GPIO3
SDAI
SDAO
SCL
ALERT
ON
GND
R9
10k
5%
CL
VOUT
12V
50A ADJUSTABLE
CONNECTOR 1
R1
34.8k
1%
+
CONNECTOR 2
12V
POWER GOOD
GP
GP
SDA
SCL
ALERT
R10
10k
5%
Y1
4MHz
12V
C3
1µF
CTIMER
15nF
C4
33pF
C5
33pF
GND
ABLS-4.000MHZ-B4-T
BACKPLANE PLUG-IN
BOARD
4281 TA02
4281f
42
For more information www.linear.com/LTC4281
LTC4281
Package Description
Please refer to http://www.linear.com/product/LTC4281#packaging for the most recent package drawings.
UFD Package
28-Lead Plastic QFN (4mm × 5mm)
(Reference LTC DWG # 05-08-1712 Rev B)
0.70 ±0.05
4.50 ±0.05
3.10 ±0.05
2.50 REF
2.65 ±0.05
3.65 ±0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
3.50 REF
4.10 ±0.05
5.50 ±0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 ±0.10
(2 SIDES)
0.75 ±0.05
PIN 1 NOTCH
R = 0.20 OR 0.35
× 45° CHAMFER
2.50 REF
R = 0.115
TYP
R = 0.05
TYP
27
28
0.40 ±0.10
PIN 1
TOP MARK
(NOTE 6)
1
2
5.00 ±0.10
(2 SIDES)
3.50 REF
3.65 ±0.10
2.65 ±0.10
(UFD28) QFN 0506 REV B
0.25 ±0.05
0.200 REF
0.50 BSC
0.00 – 0.05
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
4281f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection
of its circuits
as described
herein will not infringe on existing patent rights.
For more
information
www.linear.com/LTC4281
43
LTC4281
Typical Application
12V, 65A Application with Optical I2C Isolation and Thermal Shutdown
12V
INTVCC
5V
R10
3.3k
5V
2
8
R9
10k
6
PRF18BE471QB5RB
3 HCPL-0300 5
RS1
0.5mΩ
INTVCC
SDA
Q1
PSMN2R0-30YLE × 2
+
6
CONNECTOR 1
CONNECTOR 2
SMCJ15CA
8
INTVCC
R13
3.3k
5V
2
8
SCL
10Ω
2
5 HCPL-0300 3
R12
10k
VDD ADC+ SENSE+
NC
NC
NC
NC
6
3 HCPL-0300 5
GND
CL
VOUT
12V
65A ADJUSTABLE
UV
OV
SDAI
SDAO
SCL
ALERT
ADR0
ADR1
ADR2
INTVCC
SENSE– ADC– GATE
SOURCE
FB
ON
GPIO1
GPIO2
GPIO3
CLKIN
LTC4281
TIMER
C3
4.7µF
NC
WP
4.7kΩ
GND
CTIMER
15nF
4281 TA02
BACKPLANE PLUG-IN
BOARD
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LTC4151
High Voltage Current and Voltage Monitor with ADC 7V to 80V Single Voltage/Current Monitor with 12-Bit ADC
and I2C
LTC4210
Hot Swap Controller
Operates from 2.7V to 16.5V, Active Current Limiting, SOT23-6
LTC4211
Hot Swap Controller
Operates from 2.5V to 16.5V, Multifunction Current Control, SO-8,
MSOP-8 or MSOP-10
LTC4212
Hot Swap Controller
Operates from 2.5V to 16.5V, Power-Up Timeout, MSOP-10
LTC4215
Hot Swap Controller with I2C
Internal 8-Bit ADC, dl/dt Controlled Soft-Start
LTC4216
Hot Swap Controller
Operates from 0V to 6V, MSOP-10 or 12-Lead (4mm × 3mm) DFN
LTC4222
Dual Hot Swap Controller with ADC and I2C
2.9V to 29V Dual Controller with 10-Bit ADC, dl/dt Controlled Soft-Start
LTC4245
Multiple Supply CompactPCI or PCI Express Hot
Swap Controller with I2C
Internal 8-Bit ADC, dl/dt Controlled Soft-Start
LTC4260
Positive High Voltage Hot Swap Controller with ADC 8-Bit ADC Monitoring Current and Voltages, Supplies from 8.5V to 80V
and I2C
LTC4261
Negative High Voltage Hot Swap Controller with
ADC and I2C
10-Bit ADC Monitoring Current and Voltages, Supplies from
–12V to –100V
LTC4280
Hot Swap Controller with I2C
Internal 8-Bit ADC, Adjustable Short-Circuit Filter Time
LTC4282
Hot Swap Controller with I2C
Internal 12-Bit ADC, Power Monitoring, Dual Paths for SOA Sharing
4281f
44 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
For more information www.linear.com/LTC4281
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com/LTC4281
LT 1215 • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2015