LINER LTC2978CUPTRPBF

LTC2978
Octal PMBus Power Supply
Monitor and Controller
with EEPROM
Description
Features
n
n
n
n
n
n
n
n
n
n
n
n
n
PMBus Compliant Interface and Command Set
Configuration EEPROM
Fault Logging to Internal EEPROM
Differential Input, 15-Bit ∆Σ ADC with Less Than
±0.25% of Total Unadjusted Error
Monitors Eight Output Channels and One Input
Voltage
8-Channel Sequencer
Programmable Watchdog Timer
Eight UV/OV Voltage Supervisors
Eight 10-Bit Voltage-Buffered IDACs with Soft
Connect
Linear, Voltage Servo Adjusts Supply Voltages by
Ramping Voltage-Buffered IDAC Outputs Up/Down
Supports Multichannel Fault Management
On-Chip Digital Temperature Sensor
Available in 64-Pin 9mm × 9mm QFN Package
The LTC®2978 is an octal, PMBus compliant power supply monitor, supervisor, sequencer and margin controller. PMBus functions include warning and fault OV/UV
threshold pairs for eight output channels and one input
channel. Programmable fault response allows the power
supplies to be disabled with optional retry after a fault has
been detected. PMBus reads allow eight output voltages
and one input voltage to be monitored. In addition, odd
numbered channels can substitute sense resistor voltage
measurements for output voltage measurements. PMBus
commands support power supply sequencing and precision
point-of-load voltage servo to one of three programmed
values: margin high, margin low and nominal. A programmable watchdog timer monitors microprocessor activity
for a stalled condition and resets the micro if necessary.
The 1-wire synchronization bus supports power supply
sequencing across multiple LTC2978 devices. User programmable parameters can be stored in EEPROM. Voltage
supervisor, voltage monitor and temperature faults can
also be logged to EEPROM.
Applications
Computers
Network Servers
n
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.
Protected by U.S. Patents including 7382203 and 7420359.
n
Typical Application
Octal Power Supply Controller with PMBus Interface
VIN
4.5V < VIBUS < 15V
TO INTERMEDIATE
BUS CONVERTER
ENABLE
VPWR
VIN_SNS
VIN_EN
VDACP0
VSENSEP0
SDA
PMBus
INTERFACE
WRITE-PROTECT
LTC2978*
SCL
ALERTB
VSENSEM0
CONTROL0
VOUT_EN0
WP
PWRGD
FAULTB00
ASEL0
SHARE_CLK
R20
7.5k
LOAD
VDACM0
WDI/RESETB
TO/FROM OTHER
LTC2978s
VOUT
R30
41.2k
R10
20k
DIGITALLY
MANAGED
POWER
SUPPLY
VFB
SGND
RUN/SS
GND
TO µP RESETB INPUT
WATCHDOG
TIMER INTERRUPT
ASEL1
GND
2978 TA01
*SOME DETAILS OMITTED FOR CLARITY
ONLY ONE OF EIGHT CHANNELS SHOWN
2978fa
LTC2978
Table of Contents
Features..............................................................................................................................1
Applications.........................................................................................................................1
Typical Application.................................................................................................................1
Description..........................................................................................................................1
Absolute Maximum Ratings.......................................................................................................3
Order Information...................................................................................................................3
Pin Configuration...................................................................................................................3
Electrical Characteristics..........................................................................................................4
Timing Diagram.....................................................................................................................8
Typical Performance Characteristics............................................................................................8
Pin Functions...................................................................................................................... 12
Block Diagram..................................................................................................................... 14
Operation.......................................................................................................................... 15
Operation Overview................................................................................................................................................15
PMBus Serial Digital Interface................................................................................................................................16
Register Command Set...........................................................................................................................................18
Detailed PMBus Command Register Descriptions..................................................................................................22
Manufacturer Specific Commands..........................................................................................................................35
Watchdog...............................................................................................................................................................49
Reset......................................................................................................................................................................49
Write-Protect Pin....................................................................................................................................................49
Other Operations.....................................................................................................................................................49
Applications Information........................................................................................................ 50
PCB Assembly and Layout Suggestions.................................................................................................................61
Typical Application............................................................................................................... 62
Package Description............................................................................................................. 63
Typical Application............................................................................................................... 64
Related Parts...................................................................................................................... 64
2978fa
LTC2978
Supply Voltages:
VPWR to GND.......................................... –0.3V to 15V
VIN_SNS to GND...................................... –0.3V to 15V
VDD33 to GND........................................ –0.3V to 3.6V
VDD25 to GND...................................... –0.3V to 2.75V
Digital Input/Output Voltages:
ALERTB, SDA, SCL, CONTROL0,
CONTROL1............................................. –0.3V to 5.5V
PWRGD, SHARE_CLK,
WDI, WP...................................–0.3V to VDD33 + 0.3V
FAULTB00, FAULTB01, FAULTB10,
FAULTB11.................................–0.3V to VDD33 + 0.3V
ASEL0, ASEL1...........................–0.3V to VDD33 + 0.3V
Analog Voltages:
REFP.................................................... –0.3V to 1.35V
REFM to GND......................................... –0.3V to 0.3V
VSENSEP[7:0] to GND.................................. –0.3V to 6V
VSENSEM[7:0] to GND................................. –0.3V to 6V
VOUT_EN[3:0], VIN_EN to GND................... –0.3V to 15V
VOUT_EN[7:4] to GND.................................. –0.3V to 6V
VDACP[7:0] to GND..................................... –0.3V to 6V
VDACM[7:0] to GND ................................ –0.3V to 0.3V
Operating Temperature Range:
LTC2978C................................................. 0°C to 70°C
LTC2978I..............................................–40°C to 85°C
Storage Temperature Range................... –65°C to 125°C
Pin Configuration
TOP VIEW
64 VSENSEP6
63 VSENSEM5
62 VSENSEP5
61 VDACM7
60 VDACP7
59 VDACP6
58 VDACM6
57 VDACM5
56 VDACP5
55 VDACP4
54 VDACM4
53 VSENSEM4
52 VSENSEP4
51 VDACM3
50 VDACP3
49 VSENSEM3
(Notes 1, 2)
VSENSEM6 1
VSENSEP7 2
VSENSEM7 3
VOUT_EN0 4
VOUT_EN1 5
VOUT_EN2 6
VOUT_EN3 7
VOUT_EN4 8
VOUT_EN5 9
VOUT_EN6 10
VOUT_EN7 11
VIN_EN 12
DNC 13
VIN_SNS 14
VPWR 15
VDD33 16
48 VSENSEP3
47 VSENSEM2
46 VSENSEP2
45 VDACM2
44 VDACP2
43 VSENSEM1
42 VSENSEP1
41 VDACM1
40 VDACP1
39 VDACP0
38 VDACM0
37 VSENSEM0
36 VSENSEP0
35 REFM
34 REFP
33 ASEL1
65
VDD33 17
VDD25 18
WP 19
PWRGD 20
SHARE_CLK 21
WDI/RESET 22
FAULTB00 23
FAULTB01 24
FAULTB10 25
FAULTB11 26
SDA 27
SCL 28
ALERTB 29
CONTROL0 30
CONTROL1 31
ASEL0 32
Absolute Maximum Ratings
UP PACKAGE
64-LEAD (9mm s 9mm) PLASTIC QFN
TJMAX = 125°C, θJA = 28°C/W
EXPOSED PAD (PIN 65) IS GND, MUST BE SOLDERED TO PCB
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2978CUP#PBF
LTC2978CUP#TRPBF
LTC2978
64-Lead (9mm × 9mm) Plastic QFN
0°C to 70°C
LTC2978IUP#PBF
LTC2978IUP#TRPBF
LTC2978
64-Lead (9mm × 9mm) 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.
Consult LTC Marketing for information on non-standard lead based finish parts.
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/
2978fa
LTC2978
Electrical
Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VPWR = VIN_SNS = 12V, VDD33, VDD25 and REF pins floating, unless
otherwise indicated. CVDD33 = 100nF, CVDD25 = 100nF and CREF = 100nF.
SYMBOL
PARAMETER
Power-Supply Characteristics
VPWR
VPWR Supply Input Operating Range
IPWR
VPWR Supply Current
IVDD33
VDD33 Supply Current
VUVLO_VDD33 VDD33 Undervoltage Lockout
VDD33 Undervoltage Lockout
Hysteresis
VDD33
Supply Input Operating Range
Regulator Output Voltage
Regulator Output Short-Circuit Current
VDD25
Regulator Output Voltage
Regulator Output Short-Circuit Current
Voltage Reference Characteristics
VREF
Output Voltage
Temperature Coefficient
Hysteresis
ADC Characteristics
VIN_ADC
Voltage Sense Input Range
N_ADC
Current Sense Input Range (Odd
Numbered Channels Only When So
Configured)
Voltage Sense Resolution
Current Sense Resolution (Odd
Numbered Channels Only When So
Configured)
TUE_ADC
INL_ADC
Total Unadjusted Error
Integral Nonlinearity
DNL_ADC
VOS_ADC
GAIN_ADC
Differential Nonlinearity
Offset Error
Gain Error
tCONV_ADC
Conversion Time
CIN_ADC
fIN_ADC
Input Sampling Capacitance
Input Sampling Frequency
CONDITIONS
MIN
l
4.5
4.5V ≤ VPWR ≤ 15V, VDD33 Floating
3.13V ≤ VDD33 ≤ 3.47V, VPWR = VDD33
VDD33 Ramping Up, VPWR = VDD33
l
l
2.35
VPWR = VDD33
4.5V ≤ VPWR ≤ 15V
VPWR = 4.5V, VDD33 = 0V
3.13V ≤ VDD33 ≤ 3.47V
VPWR = VDD33 = 3.47V, VDD25 = 0V
l
3.13
3.13
75
2.35
30
l
l
l
l
l
0V ≤ VIN_ADC ≤ 6V
0mV ≤ |VIN_ADC| < 16mV
16mV ≤ |VIN_ADC| < 32mV
32mV ≤ |VIN_ADC| < 63.9mV
63.9mV ≤ |VIN_ADC| < 127.9mV
127.9mV ≤ |VIN_ADC|
VIN_ADC ≥ 1.8V (Note 4 )
Voltage Sense Mode (Note 5)
Current Sense Mode, Odd Numbered
Channels Only, 15.6µV/LSB (Note 5)
Voltage Sense Mode
Current Sense Mode, Odd Numbered
Channels Only
Voltage Sense Mode
Current Sense Mode, Odd Numbered
Channels Only
Voltage Sense Mode, VIN_ADC = 6V
Current Sense Mode, Odd Numbered
Channels Only, VIN_ADC = ±0.17V
Voltage Sense Mode (Note 6)
Current Sense Mode (Note 6)
Temperature Input (Note 6)
10
10
2.55
120
3.26
90
2.5
55
MAX
V
mA
mA
V
mV
3.47
3.47
140
2.6
80
V
V
mA
V
mA
V
ppm/°C
ppm
l
0
6
l
–0.1
–0.1
–170
0.1
6
170
l
l
122
15.625
31.25
62.5
125
250
l
l
l
l
l
l
l
l
l
6.15
24.6
24.6
1
62.5
UNITS
15
13
13
2.8
1.232
3
100
(Note 3)
Differential Voltage:
VIN_ADC = (VSENSEPn – VSENSEMn)
Single-Ended Voltage: VSENSEMn
Single-Ended Voltage: VSENSEPn, VSENSEMn
Differential Voltage: VIN_ADC
TYP
V
V
V
mV
±0.25
±854
±31.3
µV/LSB
µV/LSB
µV/LSB
µV/LSB
µV/LSB
µV/LSB
%
µV
µV
±400
±31.3
µV
µV
±250
±35
µV
µV
±0.2
±0.2
%
%
ms
ms
ms
pF
kHz
2978fa
LTC2978
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VPWR = VIN_SNS = 12V; VDD33, VDD25 and REF pins floating, unless
otherwise indicated. CVDD33 = 100nF, CVDD25 = 100nF and CREF = 100nF.
SYMBOL
IIN_ADC
PARAMETER
Input Leakage Current
Differential Input Current
Voltage Buffered IDAC Output Characteristics
N_VDACP
Resolution
VFS_VDACP
Full-Scale Output Voltage
(Programmable)
INL_VDACP
Integral Nonlinearity
DNL_VDACP Differential Nonlinearity
VOS_VDACP
Offset Voltage
VDACP
Load Regulation (VDACPn – VDACMn)
PSRR (VDACPn – VDACMn)
DC CMRR (VDACPn – VDACMn)
Leakage Current
Short-Circuit Current Low
Short-Circuit Current High
COUT
Output Capacitance
tS_VDACP
DAC Output Update Rate
Voltage Supervisor Characteristics
VIN_VS
Input Voltage Range (Programmable)
N_VS
Voltage Sensing Resolution
TUE_VS
Total Unadjusted Error
tS_VS
Update Rate
VIN_SNS Input Characteristics
VVIN_SNS
VIN_SNS Input Voltage Range
RVIN_SNS
VIN_SNS Input Resistance
TUEVIN_SNS
VIN_ON, VIN_OFF Threshold Total
Unadjusted Error
CONDITIONS
VIN_ADC = 0V, 0V ≤ VCOMMONMODE ≤ 6V,
Current Sense Mode
VIN_ADC = 0.17V, Current Sense Mode
VIN_ADC = 6V, Voltage Sense Mode
TYP
MAX
±0.5
UNITS
µA
l
80
10
250
15
nA
µA
DAC Code = 0x3FF Buffer Gain Setting_0
DAC Polarity = 1
Buffer Gain Setting_1
(Note 7)
(Note 7)
(Note 7)
VDACPn = 2.65V, IVDACPn Sourcing = 2mA
VDACPn = 0.1V, IVDACPn Sinking = 2mA
DC: 3.13V ≤ VDD33 ≤ 3.47V, VPWR = VDD33
100mV Step in 20ns with 50pF Load
–0.1V ≤ VDACMn ≤ 0.1V
VDACPn Hi-Z, 0V ≤ VDACPn ≤ 6V
VDACPn Shorted to GND
VDACPn Shorted to VDD33
VDACPn Hi-Z
Fast Servo Mode
l
l
10
1.38
2.65
VIN_VS = (VSENSEPn Low Resolution Mode
– VSENSEMn)
High Resolution Mode
Single-Ended Voltage: VSENSEMn
0V to 3.8V Range: High Resolution Mode
0V to 6V Range: Low Resolution Mode
2V ≤ VIN_VS ≤ 6V, Low Resolution Mode
1.5V < VIN_VS ≤ 3.8V, High Resolution Mode
0.8V ≤ VIN_VS ≤ 1.5V, High Resolution Mode
l
l
3V ≤ VVIN_SNS ≤ 8V
VVIN_SNS > 8V
READ_VIN Total Unadjusted Error
3V ≤ VVIN_SNS ≤ 8V
VVIN_SNS > 8V
Voltage Buffered IDAC Soft-Connect Comparator Characteristics
VOS_CMP
Offset Voltage
Temperature Sensor Characteristics
TUE_TS
Total Unadjusted Error
VOUT Enable Output (VOUT_EN [3:0]) Characteristics
VVOUT_ENn
Output High Voltage
IVOUT_ENn = –5µA, VDD33 = 3.3V
MIN
l
l
1.32
2.53
l
l
l
1.44
2.77
±2
±2.4
±10
100
100
60
40
60
±100
–4
10
l
l
l
–10
4
10
250
l
0
0
–0.1
6
3.8
0.1
4
8
±1.25
±1.0
±1.5
l
l
l
12.21
l
l
0
70
90
l
l
l
l
±3
l
11.6
12.5
V
V
V
mV/LSB
mV/LSB
%
%
%
µs
15
110
±2.0
±1.0
±1.5
±1.0
V
kΩ
%
%
%
%
±18
mV
±1
l
Bits
V
V
LSB
LSB
mV
ppm/mA
ppm/mA
dB
dB
dB
nA
mA
mA
pF
µs
°C
14.7
V
2978fa
LTC2978
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VPWR = VIN_SNS = 12V; VDD33, VDD25 and REF pins floating, unless
otherwise indicated. CVDD33 = 100nF, CVDD25 = 100nF and CREF = 100nF.
SYMBOL
IVOUT_ENn
PARAMETER
Output Sourcing Current
Output Sinking Current
Output Leakage Current
VOUT Enable Output (VOUT_EN [7:4]) Characteristics
IVOUT_ENn
Output Sinking Current
Output Leakage Current
VIN Enable Output (VIN_EN) Characteristics
VVIN_EN
Output High Voltage
IVIN_EN
Output Sourcing Current
Output Sinking Current
Leakage Current
CONDITIONS
VVOUT_ENn Pull-Up Enabled, VVOUT_ENn = 1V
Strong Pull-Down Enabled,
VVOUT_ENn = 0.4V
Weak Pull-Down Enabled, VVOUT_ENn = 0.4V
Internal Pull-Up Disabled,
0V ≤ VVOUT_ENn ≤ 15V
l
MIN
–5
3
TYP
–6
5
MAX
–8
8
l
33
50
60
±1
µA
µA
3
6
9
mA
±1
µA
14.7
–8
8
60
±1
V
µA
mA
µA
µA
l
l
Strong Pull-Down Enabled,
VOUT_ENn = 0.1V
0V ≤ VVOUT_ENn ≤ 6V
l
IVIN_EN = –5µA, VDD33 = 3.3V
VIN_EN Pull-Up Enabled, VVIN_EN = 1V
Strong Pull-Down Enabled, VVIN_EN = 0.4V
Weak Pull-Down Enabled, VVIN_EN = 0.4V
Internal Pull-Up Disabled,
0V ≤ VVIN_EN ≤ 15V
l
l
l
l
l
11.6
–5
3
33
12.5
–6
5
50
l
EEPROM Characteristics
Endurance
(Note 8)
l
0°C < TJ < 85°C During EEPROM Write
10,000
Operations
l
Retention
(Note 8)
TA < 85°C
10
Mass_Write Mass Write Operation Time (Note 9)
STORE_USER_ALL, 0°C < TJ < 85°C During l
EEPROM Write Operations
Digital Inputs SCL, SDA, CONTROL0, CONTROL1, WDI/RESETB, FAULTB00, FAULTB01, FAULTB10, FAULTB11, WP
VIH
High Level Input Voltage
l
VIL
VHYST
ILEAK
Low Level Input Voltage
Input Hysteresis
Input Leakage Current
l
tSP
Pulse Width of Spike Suppressed
tRESETB
Pulse Width to Assert Reset
tWDI
Pulse Width to Reset Watchdog Timer
fWDI
Watchdog Interrupt Input Frequency
CIN
Digital Input Capacitance
Digital Input SHARE_CLK
VIH
High Level Input Voltage
VIL
Low Level Input Voltage
fSHARE_CLK_IN Input Frequency Operating Range
tLOW
Assertion Low Time
tRISE
Rise Time
ILEAK
Input Leakage Current
CIN
Input Capacitance
Cycles
440
4100
2.1
1.5
l
±2
V
mV
µA
l
±2
µA
10
98
l
l
300
0.3
200
1
l
10
l
1.6
0.8
110
1.1
450
±1
l
l
VSHARE_CLK < 0.8V
VSHARE_CLK < 0.8V to VSHARE_CLK > 1.6V
0V ≤ VSHARE_CLK ≤ VDD33 + 0.3V
Years
ms
V
20
0V ≤ VPIN ≤ 5.5V, SDA, SCL, CONTROLx
Pins Only
0V ≤ VPIN ≤ VDD33 + 0.3V, FAULTBxx,
WDI/RESETB, WP Pins Only
FAULTBxx, CONTROLx Pins Only
SDA, SCL Pins Only
VWDI/RESETB ≤ 1.5V
VWDI/RESETB ≤ 1.5V
UNITS
µA
mA
l
90
0.825
l
l
10
µs
ns
µs
µs
MHz
pF
V
V
kHz
µs
ns
µA
pF
2978fa
LTC2978
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VPWR = VIN_SNS = 12V; VDD33, VDD25 and REF pins floating, unless
otherwise indicated. CVDD33 = 100nF, CVDD25 = 100nF and CREF = 100nF.
SYMBOL
PARAMETER
CONDITIONS
Digital Outputs SDA, ALERTB, PWRGD, SHARE_CLK, FAULTB00, FAULTB01, FAULTB10, FAULTB11
VOL
Digital Output Low Voltage
ISINK = 3mA
fSHARE_CLK_OUT Output Frequency Operating Range
5.49kΩ Pull-Up to VDD33
Digital Inputs ASEL0,ASEL1
VIH
Input High Threshold Voltage
VIL
Input Low Threshold Voltage
IIH,IL
High, Low Input Current
ASEL[1:0] = 0, VDD33
IIH, Z
Hi-Z Input Current
CIN
Input Capacitance
Serial Bus Timing Characteristics
fSCL
Serial Clock Frequency (Note 10)
tLOW
Serial Clock Low Period (Note 10)
tHIGH
Serial Clock High Period (Note 10)
tBUF
Bus Free Time Between Stop and Start
(Note 10)
tHD,STA
Start Condition Hold Time (Note 10)
tSU,STA
Start Condition Setup Time (Note 10)
tSU,STO
Stop Condition Setup Time (Note 10)
tHD,DAT
Data Hold Time (LTC2978 Receiving
Data) (Note 10)
Data Hold Time (LTC2978 Transmitting
Data) (Note 10)
tSU,DAT
Data Setup Time (Note 10)
tSP
Pulse Width of Spike Suppressed
(Note 10)
tTIMEOUT_BUS Time Allowed to Complete any PMBus Longer Timeout = 0
Command After Which Time SDA Will Longer Timeout = 1
Be Released and Command Terminated
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating for extended periods may affect device reliability and
lifetime.
Note 2: All currents into device pins are positive. All currents out of device
pins are negative. All voltages are referenced to ground unless otherwise
specified. If power is supplied to the chip via the VDD33 pin only, connect
VPWR and VDD33 pins together.
Note 3: Hysteresis in the output voltage is created by package stress that
differs depending on whether the IC was previously at a higher or lower
temperature. Output voltage is always measured at 25°C, but the IC is
cycled to 85°C or –40°C before successive measurements. Hysteresis is
roughly proportional to the square of the temperature change.
Note 4: TUE(%) is defined as:
Gain Error (%) + 100 • (INL + VOS)/VIN.
Note 5: Integral nonlinearity (INL) is defined as the deviation of a code
from a straight line passing through the actual endpoints of the transfer
curve (0V and 6V). The deviation is measured from the center of the
quantization band.
MIN
TYP
MAX
UNITS
l
90
100
0.4
110
V
kHz
l
VDD33 – 0.5
0.5
±95
±24
V
V
µA
µA
pF
l
l
l
l
10
l
l
l
l
10
1.3
0.6
1.3
l
600
600
600
0
l
300
l
100
l
l
l
400
ns
ns
ns
ns
900
25
200
ns
ns
ns
98
l
l
kHz
µs
µs
µs
35
280
ms
ms
Note 6: The time between successive ADC conversions (latency of the
ADC) for any given channel is given as: 36.9ms + (6.15ms • number of
ADC channels configured in Low Resolution mode) + (24.6ms • number of
ADC channels configured in High Resolution mode).
Note 7: Nonlinearity is defined from the first code that is greater than or
equal to the maximum offset specification to full-scale code, 1023.
Note 8: EEPROM endurance and retention are guaranteed by design,
characterization and correlation with statistical process controls. The
minimum retention specification applies for devices whose EEPROM has
been cycled less than the minimum endurance specification.
Note 9: The LTC2978 will not acknowledge any PMBus write commands
when a STORE_USER_ALL command is being executed.
Note 10: Maximum capacitive load, CB, for SCL and SDA is 400pF. Data
and clock rise time (tr) and fall time (tf) are: (20 + 0.1• CB) (ns) < tr <
300ns and (20 + 0.1 • CB) (ns) < tf < 300ns. CB = capacitance of one bus
line in pF. SCL and SDA external pull-up voltage, VIO, is 3.13V < VIO < 5.5V.
2978fa
LTC2978
Timing Diagram
SDA
tf
tLOW
tr
tSU(DAT)
tHD(SDA)
tf
tSP
tr
tBUF
SCL
tHD(STA)
tHD(DAT)
tSU(STA)
tHIGH
tSU(STO)
2978 TD
START
CONDITION
REPEATED START
CONDITION
STOP
CONDITION
START
CONDITION
Typical Performance Characteristics
ADC Total Unadjusted Error
vs Temperature
Temperature Sensor Error
vs Temperature
Reference Voltage vs Temperature
1.6
0.035
1.2350
1.4
0.030
REFERENCE OUTPUT VOLTAGE (V)
1.2355
1.2345
1.2
1.2340
ERROR (%)
1.2330
0.025
1.0
ERROR (°C)
1.2335
0.8
0.6
1.2325
THREE TYPICAL PARTS
1.2310
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
0
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
ADC Zero Code Center Offset
Voltage vs Temperature
2978 G03
ADC-INL
3.0
VOLTAGE SENSE MODE
ADC-DNL
0.8
122µV/LSB
0.6
2.5
–40
2.0
0.4
–60
1.5
0.2
–80
–100
–120
ERROR (LSBs)
–20
ERROR (LSBs)
VOS (µV)
0
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
2978 G02
2978 G01
0
0.015
0.005
0.2
1.2315
0.020
0.010
0.4
1.2320
1.0
122µV/LSB
0
–0.2
0.5
–0.4
0
–140
–0.5
–0.6
–160
–1.0
–0.8
–180
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
–1.5
–0.2
2978 G04
ADC VIN = 1.8V
0.8
1.8
2.8
3.8
4.8
INPUT VOLTAGE (V)
5.8
2978 G05
–1.0
–0.2
0.8
1.8
2.8
3.8
4.8
INPUT VOLTAGE (V)
5.8
2978 G06
2978fa
LTC2978
Typical Performance Characteristics
0
ADC Rejection
vs Frequency at VIN (Zoom)
–20
–40
–40
–40
–60
–80
–120
REJECTION (dB)
–20
–100
–60
–80
0
12500
25000 37500 50000
FREQUENCY (Hz)
62500
–120
0
3125
6250
9375
FREQUENCY (Hz)
–60
–80
1200
0
3125
6250
9375
FREQUENCY (Hz)
0
VIN = 0V
HIGH RESOLUTION MODE
–0.05
600
400
–0.20
–0.25
–0.35
–10
0
10
READ_VOUT (µV)
–0.40
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
20
2978 G12
Voltage Buffered IDAC Full-Scale
Output Voltage vs Temperature
ADC High Resolution Mode
Differential Input Current
90
2.698
8
80
2.696
3
2
1
0
0
1
2
3
4
INPUT VOLTAGE (V)
5
6
2978 G13
2.694
70
OUTPUT VOLTAGE (V)
DIFFERENTIAL INPUT CURRENT (nA)
9
4
VIN = 0.8V
HIGH RESOLUTION MODE
–0.15
2978 G11
Input Sampling Current
vs Differential Input Voltage
5
62500
–0.30
2978 G10
6
25000 37500 50000
FREQUENCY (Hz)
–0.10
800
0
–20
12500
7
12500
Voltage Supervisor Total
Unadjusted Error vs Temperature
200
–100
–120
0
2978 G09
ADC Noise Histogram
NUMBER OF READINGS
REJECTION (dB)
–40
–80
2978 G08
1000
–20
–60
–120
12500
ERROR (%)
0
ADC Rejection vs Frequency
at VIN (Current Sense Mode, Zoom)
ADC Rejection vs Frequency
at VIN (Current Sense Mode)
–100
–100
2978 G07
INPUT SAMPLING CURRENT (µA)
0
–20
REJECTION (dB)
REJECTION (dB)
0
ADC Rejection
vs Frequency at VIN
60
50
40
30
2.692
2.690
2.688
2.686
2.684
20
2.682
10
2.680
0
0
20 40 60 80 100 120 140 160 180
DIFFERENTIAL INPUT VOLTAGE (mV)
2978 G14
2.678
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
2978 G15
2978fa
LTC2978
Typical Performance Characteristics
1.0
2.3
0.8
0.8
2.1
0.6
0.6
1.9
0.4
0.4
1.7
1.5
1.3
ERROR (LSBs)
1.0
0.2
0
–0.2
0.2
0
–0.2
1.1
–0.4
–0.4
0.9
–0.6
–0.6
0.7
–0.8
–0.8
0.5
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
–1.0
0
200
600
400
DAC CODE
2.688
2.686
2.684
2.682
2.678
85°C
0.1034
25°C
0.1032
0.1030
–40°C
0.1028
–40°C
2.680
0 –0.25 –0.5 –0.75 –1 –1.25 –1.50 1.75
CURRENT (mA)
–2
SHORT-CIRCUIT CURRENT (mA)
OUTPUT VOLTAGE (V)
25°C
800
0.1026
1000
9.00
0.1036
2.694
2.692
600
400
DAC CODE
IDAC Voltage Buffer Short-Circuit
Current vs Temperature
0.1038
2.690
200
2978 G18
IDAC Voltage Buffer Load
Regulation (Sinking)
85°C
2.696
0
2978 G17
Voltage Buffered IDAC Load
Regulation (Sourcing)
2.698
–1.0
1000
800
2978 G16
OUTPUT VOLTAGE (V)
Voltage Buffered IDAC DNL
Voltage Buffered IDAC-INL
2.5
ERROR (LSBs)
OFFSET ERROR (mV)
Voltage Buffered IDAC Offset
Voltage vs Temperature
0
0.25 0.5 0.75 1 1.25 1.5 1.75
CURRENT (mA)
2978 G19
2
8.95
8.90
8.85
8.80
8.75
8.70
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
2978 G21
2978 G20
IDAC Voltage Buffer Soft Connect
Transient Response when
Transitioning from Hi-Z State to
ON State
IDAC Voltage Buffer Transient
Response to 1LSB DAC Code
Change
IDAC Voltage Buffer Soft Connect
Transient Response when
Transitioning from ON State to
Hi-Z State
CODE ‘h200
HI-Z
500µV/DIV
HI-Z
10mV/DIV
10mV/DIV
CONNECTED
CODE ‘h1FF
2µs/DIV
2978 G22
500µs/DIV
100k SERIES RESISTANCE ON
CODE: ‘h1FF
CONNECTED
2978 G23
500µs/DIV
100k SERIES RESISTANCE ON
CODE: ‘h1FF
2978 G24
2978fa
10
LTC2978
Typical Performance Characteristics
400
3.270
300
–86
85°C
200
3.265
3.260
3.255
3.250
3.245
25°C
100
–40°C
0
–100
–200
–300
3.240
–400
3.235
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
–500
4.5
10.16
6
7.5
9
10.5
VPWR (V)
12
13.5
9.9
3.1
3.2
3.3
3.4
3.5
3.6
VDD33 (V)
14.0
VPWR = 12V
10.12
10.10
13.5
10.06
11.0
10.0
9.5
10.02
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
100
0.6
1.2
0.5
VOLTS (V)
VOLTS (V)
100
1000
25°C
0.6
2978 G31
0
7
0.4
85°C
0.8
–40°C
85°C
0.3
25°C
0.2
–40°C
0.1
0.2
10
1
FREQUENCY (kHz)
6
VOUT_EN[7:4] VOL vs Current
1.4
0.4
0.1
2
3
4
5
CURRENT SOURCING (µA)
1
2978 G30
1.0
0.01
0.01
0
2978 G29
1000
0.1
–40°C
10.5
VOUT_EN[3:0] and VIN_EN VOL
vs Current
1
25°C
12.5
11.5
10.08
Voltage Buffered IDAC Output
Impedance vs Frequency
10
85°C
13.0
12.0
2978 G28
OUTPUT IMPEDANCE (Ω)
VOUT_EN[3:0] and VIN_EN Output
High Voltage vs Load Current
10.04
3
–98
2978 G27
CHARGE PUMP OUTUPT HIGH VOLTAGE (V)
SUPPLY CURRENT (mA)
SUPPLY CURRENT (mA)
10.0
–96
–102
–50 –35 –20 –5 10 25 40 55 70 85 100
TEMPERATURE (°C)
15
10.14
10.4
10.1
–94
Supply Current vs Temperature
VPWR = VDD33
10.2
–92
2978 G26
Supply Current vs Supply Voltage
10.3
–90
–100
2978 G25
10.5
–88
SHORT-CIRCUIT CURRENT (mA)
3.275
9.8
VDD33 Regulator Short-Circuit
Current vs Temperature
VDD33 Regulator Line Regulation
$VDD33 (ppm)
VDD33 OUTPUT VOLTAGE (V)
VDD33 Regulator Output Voltage
vs Temperature
0
2
4
8
6
ISINK (mA)
10
12
2978 G32
0
0
4
8
12
16
ISINK (mA)
20
24
2978 G33
2978fa
11
LTC2978
Typical Performance Characteristics
PWRGD and FAULTBzn VOL
vs Current
ALERTB VOL vs Current
1.2
1.4
1.0
1.2
1.0
VOLTS (V)
VOLTS (V)
0.8
0.6
0.4
25°C
0.6
–40°C
0.4
85°C
25°C
–40°C
0.2
0
85°C
0.8
0
2
4
6
8
ISINK (mA)
10
0.2
12
2978 G34
0
0
2
4
8
6
ISINK (mA)
10
12
2978 G35
Pin Functions
PIN NAME
VSENSEM6
VSENSEP7
VSENSEM7
VOUT_EN0
VOUT_EN1
VOUT_EN2
VOUT_EN3
VOUT_EN4
VOUT_EN5
VOUT_EN6
VOUT_EN7
VIN_EN
DNC
VIN_SNS
PIN NUMBER
PIN TYPE
1*
In
2*
In
3*
In
4
Out
5
Out
6
Out
7
Out
8
Out
9
Out
10
Out
11
Out
12
0ut
13
Do Not Connect
14
In
VPWR
15
In
VDD33
16
In/Out
VDD33
VDD25
WP
PWRGD
17
18
19
20
In
In/Out
In
Out
SHARE_CLK
WDI/RESET
21
22
In/Out
In
DESCRIPTION
DC/DC Converter Differential (–) Output Voltage-6 Sensing Pin
DC/DC Converter Differential (+) Output Voltage or Current-7 Sensing Pin
DC/DC Converter Differential (–) Output Voltage or Current-7 Sensing Pin
DC/DC Converter Enable-0 Pin. Output High Voltage Optionally Pulled Up to 12V by 5µA
DC/DC Converter Enable-1 Pin. Output High Voltage Optionally Pulled Up to 12V by 5µA
DC/DC Converter Enable-2 Pin. Output High Voltage Optionally Pulled Up to 12V by 5µA
DC/DC Converter Enable-3 Pin. Output High Voltage Optionally Pulled Up to 12V by 5µA
DC/DC Converter Open-Drain Pull-Down Output-4
DC/DC Converter Open-Drain Pull-Down Output-5
DC/DC Converter Open-Drain Pull-Down Output-6
DC/DC Converter Open-Drain Pull-Down Output-7
DC/DC Converter VIN ENABLE Pin. Output High Voltage Optionally Pulled Up to 12V by 5µA
Do Not Connect to This Pin
VIN SENSE Input. This Voltage is Compared Against the VIN On and Off Voltage Thresholds in Order to
Determine When to Enable and Disable, Respectively, the Downstream DC/DC Converters
VPWR Serves as the Unregulated Power Supply Input to the Chip (4.5V to 15V). If a 4.5V to 15V Supply
Voltage is Unavailable, Short VPWR to VDD33 and Power the Chip Directly from a 3.3V Supply
If Shorted to VPWR, it Serves as 3.13V to 3.47V Supply Input Pin. Otherwise it is a 3.3V Internally
Regulated Voltage Output (Use 100nF Decoupling Capacitor to GND)
Input for Internal 2.5V Sub-Regulator. Short This Pin to Pin 16
2.5V Internally Regulated Voltage Output. Bypass to GND with a 0.1µF Capacitor
Digital Input. Write-Protect Input Pin, Active High
Power Good Open-Drain Output. Indicates When Outputs are Power Good. Can be Used as System
Power-On Reset
Bidirectional Clock Sharing Pin. Connect a 5.49k Pull-Up Resistor to VDD33
Watchdog Timer Interrupt and Chip Reset Input. Connect a 10k Pull-Up Resistor to VDD33. Rising Edge
Resets Watchdog Counter. Holding This Pin Low for More Than tRESETB Resets the Chip
2978fa
12
LTC2978
Pin Functions
FAULTB00
23
In/Out
Open-Drain Output and Digital Input. Active Low Bidirectional Fault Indicator-00. Connect a 10k Pull-Up
Resistor to VDD33
FAULTB01
24
In/Out
Open-Drain Output and Digital Input. Active Low Bidirectional Fault Indicator-01. Connect a 10k Pull-Up
Resistor to VDD33
FAULTB10
25
In/Out
Open-Drain Output and Digital Input. Active Low Bidirectional Fault Indicator-10. Connect a 10k Pull-Up
Resistor to VDD33
FAULTB11
26
In/Out
Open-Drain Output and Digital Input. Active Low Bidirectional Fault Indicator-11. Connect a 10k Pull-Up
Resistor to VDD33
SDA
27
In/Out
PMBus Bidirectional Serial Data Pin
SCL
28
In
PMBus Serial Clock Input Pin (400kHz Maximum)
ALERTB
29
Out
Open-Drain Output. Generates an Interrupt Request in a Fault/Warning Situation
CONTROL0
30
In
Control Pin 0 Input
CONTROL1
31
In
Control Pin 1 Input
ASEL0
32
In
Ternary Address Select Pin 0 Input. Connect to VDD33, GND or Float to Encode 1 of 3 Logic States
ASEL1
33
In
Ternary Address Select Pin 1 Input. Connect to VDD33, GND or Float to Encode 1 of 3 Logic States
REFP
34
Out
Reference Voltage Output. Needs 0.1µF Decoupling Capacitor to REFM
REFM
35
Out
Reference Return Pin. Needs 0.1µF Decoupling Capacitor to REFP.
VSENSEP0
36*
In
DC/DC Converter Differential (+) Output Voltage-0 Sensing Pin
VSENSEM0
37*
In
DC/DC Converter Differential (–) Output Voltage-0 Sensing Pin
VDACM0
38
Out
Voltage Buffered IDAC0 Return. Connect to Channel 0 DC/DC Converter’s GND Sense or Return to GND
VDACP0
39
Out
Voltage Buffered IDAC0 Output
VDACP1
40
Out
Voltage Buffered IDAC1 Output
VDACM1
41
Out
Voltage Buffered IDAC1 Return. Connect to Channel 1 DC/DC Converter’s GND Sense or Return to GND
VSENSEP1
42*
In
DC/DC Converter Differential (+) Output Voltage or Current-1 Sensing Pins
VSENSEM1
43*
In
DC/DC Converter Differential (–) Output Voltage or Current-1 Sensing Pins
VDACP2
44
Out
Voltage Buffered IDAC2 Output
VDACM2
45
Out
Voltage Buffered IDAC2 Return. Connect to Channel 2 DC/DC Converter’s GND Sense or Return to GND
VSENSEP2
46*
In
DC/DC Converter Differential (+) Output Voltage-2 Sensing Pin
VSENSEM2
47*
In
DC/DC Converter Differential (–) Output Voltage-2 Sensing Pin
VSENSEP3
48*
In
DC/DC Converter Differential (+) Output Voltage or Current-3 Sensing Pins
VSENSEM3
49*
In
DC/DC Converter Differential (–) Output Voltage or Current-3 Sensing Pins
VDACP3
50
Out
Voltage Buffered IDAC3 Output
VDACM3
51
Out
Voltage Buffered IDAC3 Return. Connect to Channel 3 DC/DC Converter’s GND Sense or Return to GND
VSENSEP4
52*
In
DC/DC Converter Differential (+) Output Voltage-4 Sensing Pin
VSENSEM4
53*
In
DC/DC Converter Differential (–) Output Voltage-4 Sensing Pin
VDACM4
54
Out
Voltage Buffered IDAC4 Return. Connect to Channel 4 DC/DC Converter’s GND Sense or Return to GND
VDACP4
55
Out
Voltage Buffered IDAC4 Output
VDACP5
56
Out
Voltage Buffered IDAC5 Output
VDACM5
57
Out
Voltage Buffered IDAC5 Return. Connect to Channel 5 DC/DC Converter’s GND Sense or Return to GND
VDACM6
58
Out
Voltage Buffered IDAC6 Return. Connect to Channel 6 DC/DC Converter’s GND Sense or Return to GND
VDACP6
59
Out
Voltage Buffered IDAC6 Output
VDACP7
60
Out
Voltage Buffered IDAC7 Output
VDACM7
61
Out
Voltage Buffered IDAC7 Return. Connect to Channel 7 DC/DC Converter’s GND Sense or Return to GND
VSENSEP5
62*
In
DC/DC Converter Differential (+) Output Voltage or Current-5 Sensing Pins
VSENSEM5
63*
In
DC/DC Converter Differential (–) Output Voltage or Current-5 Sensing Pins
VSENSEP6
64*
In
DC/DC Converter Differential (+) Output Voltage-6 Sensing Pin
GND
65
Ground
Exposed Pad, Must be Soldered to PCB
*Any unused VSENSEPn or VSENSEMn pins must be tied to GND.
2978fa
13
LTC2978
Block Diagram
3.3V REGULATOR
VIN
VOUT
VPWR 15
VDD
VDD33 16
2.5V REGULATOR
VIN
VOUT
VDD25 18
VIN_SNS 14
3R
VSENSEM0
VSENSEP0
R
VSENSEM1
GND 65
INTERNAL
TEMP
SENSOR
VSENSEP1
36 VSENSEP0
VSENSEM2
37 VSENSEM0
VSENSEP2
42 VSENSEP1
VSENSEM3
43 VSENSEM1
VSENSEP3
46 VSENSEP2
VSENSEM4
MUX
VSENSEP4
CMP0
VSENSEM5
VSENSEP5
+
–
+
–
VDD33 17
47 VSENSEM2
+
–
48 VSENSEP3
10-BIT
VDAC
49 VSENSEM3
52 VSENSEP4
VSENSEM6
53 VSENSEM4
VSENSEP6
62 VSENSEP5
VSENSEM7
63 VSENSEM5
VSENSEP7
64 VSENSEP6
+ 15-BIT
– $∑ ADC
1 VSENSEM6
+SC
2 VSENSEP7
CMP0
ADC
CLOCKS
IDAC0
10 BITS
3 VSENSEM7
–
+
39 VDACP0
VBUF0
–
40 VDACP1
VDD
44 VDACP2
50 VDACP3
REFERENCE
1.232V
(TYP)
REFP 34
55 VDACP4
56 VDACP5
REFM 35
59 VDACP6
60 VDACP7
38 VDACM0
41 VDACM1
SCL 28
SDA 27
ALERTB 29
ASEL0 32
45 VDACM2
NONVOLATILE MEMORY
PMBus
INTERFACE
(400kHz I2C
COMPATIBLE)
ASEL1 33
51 VDACM3
EEPROM
54 VDACM4
RAM
57 VDACM5
ADC_RESULTS
MONITOR LIMITS
SERVO TARGETS
58 VDACM6
61 VDACM7
WP 19
4 VOUT_EN0
OUTPUT
CONFIG
CONTROL0 30
CONTROL1 31
OSCILLATOR
WDI/RESET 22
FAULTB00 23
FAULTB01 24
FAULTB10 25
FAULTB11 26
PWRGD 20
SHARE_CLK 21
CONTROLLER
PMBus ALGORITHM
FAULT PROCESSOR
WATCHDOG
SEQUENCER
CLOCK
GENERATION
6 VOUT_EN2
7 VOUT_EN3
12 VIN_EN
VDD
UVLO
5 VOUT_EN1
8 VOUT_EN4
OPEN-DRAIN
OUTPUT
9 VOUT_EN5
10 VOUT_EN6
11 VOUT_EN7
2978 BD
2978fa
14
LTC2978
Operation
Operation Overview
n
The LTC2978 is a PMBus programmable power supply
controller, monitor, sequencer and voltage supervisor that
can perform the following operations:
n
Accept PMBus compatible programming commands.
n
n
Provide DC/DC converter input voltage and output voltage/current read back through the PMBus interface.
n
Control the output of modules that set voltage with a
trim pin or modules that set the output voltage using
an external resistor feedback network.
n
Sequence the start-up of DC/DC converters via PMBus
programming and the CONTROL input pins.
n
Trim the DC/DC converter output voltage (typically in
0.1% steps), in closed-loop servo operating mode,
through PMBus programming.
n
Margin the DC/DC converter output voltage to PMBus
programmed limits (typically ±10%).
n
Allow the user to trim or margin the DC/DC converter
output voltage in a manual operating mode by providing
direct access to the margin DAC.
n
Supervise the DC/DC converter output voltage, input
voltage, and the LTC2978 die temperature for overvalue/undervalue conditions with respect to PMBus
programmed limits and generate appropriate faults and
warnings.
n
Respond to a fault condition by either continuing operation indefinitely, latching off after a programmable
de-glitch period or latching off immediately. A retry
mode may be used to automatically recover from a
latched-off condition.
n
Stop trimming the DC/DC converter output voltage after
it reached the initial margin or nominal target. Optionally
allows servo to resume if target drifts outside of VOUT
warning limits.
Store command register contents to EEPROM through
PMBus programming.
Restore EEPROM contents through PMBus programming or on POR.
Report the DC/DC converter output voltage status
through the PMBus interface and the power good
output.
Generate interrupt requests by asserting the ALERTB
pin in response to supported PMBus faults.
n
Shut down multiple DC/DC converters in response to
a fault through the FAULTBz0 and FAULTBz1 pins.
n
Synchronize sequencing delays or shutdown for multiple
devices using the SHARE_CLK pin.
n
Software and hardware write protect the command
registers.
n
Disable the input voltage to the supervised DC/DC
converters in response to output voltage OV and UV
faults.
n
Log telemetry and status data to EEPROM in response
to a faulted-off condition
n
Supervise an external microcontroller’s activity for a
stalled condition with a programmable watchdog timer
and reset it if necessary.
n
Prevent a DC/DC converter from re-entering the ON
state after a power cycle until a programmable interval
(MFR_RESTART_DELAY) has elapsed and its output
has decayed below a programmable threshold voltage
(MFR_VOUT_DISCHARGE_THRESHOLD).
n
Record minimum and maximum observed values of
input voltage, output voltages and temperature.
n
n
2978fa
15
LTC2978
Operation
PMBus Serial Digital Interface
The LTC2978 communicates with a host (master) using
the standard PMBus serial bus interface. The Timing
Diagram shows the timing relationship of the signals on
the bus. The two bus lines, SDA and SCL, must be high
when the bus is not in use. External pull-up resistors or
current sources are required on these lines.
The LTC2978 is a slave device. The master can communicate
with the LTC2978 using the following formats:
Master transmitter, slave receiver
Figures 1-10 illustrate the aforementioned SMBus protocols. All transactions support PEC (parity error check)
and GCP (group command protocol). The Block Read
supports 256 bytes of returned data. For this reason, the
PMBus timeout may be extended using the Mfr_config_all_
longer_pmbus_timeout setting.
The LTC2978 will not acknowledge any PMBus command if
it is still busy with a STORE_USER_ALL, RESTORE_USER_
ALL, MFR_CONFIG or if fault log data is being written to
the EEPROM. Status_word_busy will also be set.
n
Slave Address
Master receiver, slave transmitter
n
The LTC2978 can be configured to respond to one of nine
addresses for a given MFR_I2C_BASE_ADDRESS value
(the factory default value for this register is 7’h5C). In
addition, the LTC2978 will always respond to its global
address and the PMBus Alert Response address regardless of the state of the address select pins.
The following SMBus protocols are supported:
Write Byte, Write Word, Send Byte
n
Read Byte, Read Word, Block Read
n
Alert Response Address
n
By connecting each of the address inputs to VDD33, GND,
or by floating them, the user determines the slave address
as shown in Table 1.
Table 1. LTC2978 Address Look-Up Table
DESCRIPTION
HEX DEVICE
ADDRESS
BINARY DEVICE ADDRESS
ADDRESS PINS
7’h
8’h
6
5
4
3
2
1
0
R/W
ASEL1
ASEL0
Alert Response
0C
19
0
0
0
1
1
0
0
1
X
X
Global
5B
B6
1
0
1
1
0
1
1
0
X
X
0*
5C
B8
1
0
1
1
1
0
0
0
L
L
1
5D
BA
1
0
1
1
1
0
1
0
L
NC
2
5E
BC
1
0
1
1
1
1
0
0
L
H
3
5F
BE
1
0
1
1
1
1
1
0
NC
L
4
60
C0
1
1
0
0
0
0
0
0
NC
NC
5
61
C2
1
1
0
0
0
0
1
0
NC
H
6
62
C4
1
1
0
0
0
1
0
0
H
L
7
63
C6
1
1
0
0
0
1
1
0
H
NC
8
64
C8
1
1
0
0
1
0
0
0
H
H
H = Tie to VDD33, NC = No Connect, Open or Float, L = Tie to GND, X = Don’t Care
*MFR_I2C_BASE_ADDRESS = 7’h5C (Factory Default)
2978fa
16
LTC2978
Operation
1
S
7
1
1
8
1
SLAVE ADDRESS Wr A COMMAND CODE A
8
1
1
DATA BYTE
A
P
2978 F01
Figure 1. Write Byte Protocol
1
S
7
1
1
8
1
SLAVE ADDRESS Wr A COMMAND CODE A
8
1
8
1
1
DATA BYTE LOW
A
DATA BYTE HIGH
A
P
2978 F02
Figure 2. Write Word Protocol
1
S
7
1
1
8
1
SLAVE ADDRESS Wr A COMMAND CODE A
8
1
8
1
1
DATA BYTE
A
PEC
A
P
2978 F03
Figure 3. Write Byte Protocol with PEC
1
S
7
1
1
8
1
SLAVE ADDRESS Wr A COMMAND CODE A
8
1
8
1
8
1
1
DATA BYTE LOW
A
DATA BYTE HIGH
A
PEC
A
P
2978 F04
Figure 4. Write Word Protocol with PEC
1
S
7
1
1
SLAVE ADDRESS Wr A
8
1
1
DATA BYTE
A
P
2978 F05
Figure 5. Send Byte Protocol
1
S
7
1
1
SLAVE ADDRESS Wr A
8
1
8
1
1
DATA BYTE
A
PEC
A
P
2978 F06
Figure 6. Send Byte Protocol with PEC
1
S
1
1
SLAVE ADDRESS Wr A COMMAND CODE A
7
1
1
8
S
7
1
1
SLAVE ADDRESS Rd A
8
1
DATA BYTE LOW
A
1
1
DATA BYTE HIGH A
8
P
1 2978 F07
Figure 7. Read Word Protocol
1
S
1
1
SLAVE ADDRESS Wr A COMMAND CODE A
7
1
1
8
S
7
1
1
SLAVE ADDRESS Rd A
8
1
DATA BYTE LOW
A
8
1
DATA BYTE HIGH A
8
1
1
PEC
A
P
1 2978 F08
Figure 8. Read Word Protocol with PEC
1
S
1
1
SLAVE ADDRESS Wr A COMMAND CODE A
7
1
1
8
S
8
1
1
SLAVE ADDRESS Rd A
8
1
1
DATA BYTE
A
P
1 2978 F09
Figure 9. Read Byte Protocol
1
S
1
1
SLAVE ADDRESS Wr A COMMAND CODE A
7
1
1
8
S
8
1
1
SLAVE ADDRESS Rd A
8
1
DATA BYTE
A
PEC
1
1
A
P
1 2978 F10
Figure 10. Read Byte Protocol with PEC
2978fa
17
LTC2978
Operation
Register Command Set
Summary
DATA
NV
LENGTH COMMAND MEMORY
(BITS) BYTE VALUE
TYPE
DEFAULT
VALUE
PAGED
?
‘h00
N
‘h00
Y
EEPROM
‘h12
Y
‘h03
NA
Y
8
‘h10
EEPROM
‘h00
N
W
0
‘h15
NA
N
Restore entire operating memory from
EEPROM.
W
0
‘h16
NA
N
CAPABILITY
The CAPABILITY command provides a
way for a host system to determine the
capabilities of the PMBus device.
R
8
‘h19
ROM
‘hE0
N
VOUT_MODE
Output voltage format control.
R
8
‘h20
ROM
‘h13
Y
VOUT_COMMAND
Servo DC/DC converter output voltage
value setting.
R/W
16
‘h21
EEPROM
‘h2000
Y
VOUT_MAX
The VOUT_MAX command sets an upper
limit on the output voltage, in volts, the
unit can command regardless of any other
commands or combinations.
R/W
16
‘h24
EEPROM
‘h8000
Y
VOUT_MARGIN_HIGH
Margin high DC/DC converter output
voltage limit setting.
R/W
16
‘h25
EEPROM
‘h219A
Y
VOUT_MARGIN_LOW
Margin low DC/DC converter output
voltage limit setting.
R/W
16
‘h26
EEPROM
‘h1E66
Y
VIN_ON
The VIN_ON command sets the input
voltage, in volts, at which the unit should
start power conversion.
R/W
16
‘h35
EEPROM
‘hD280
N
VIN_OFF
The VIN_OFF command sets the input
voltage, in volts, at which the unit should
stop power conversion.
R/W
16
‘h36
EEPROM
‘hD240
N
VOUT_OV_FAULT_LIMIT
Overvoltage DC/DC converter fault limit
setting.
R/W
16
‘h40
EEPROM
‘h2333
Y
VOUT_OV_FAULT_RESPONSE
The VOUT_OV_FAULT_RESPONSE
command instructs the device on what
action to take in response to an output
overvoltage fault.
R/W
8
‘h41
EEPROM
‘h80
Y
VOUT_OV_WARN_LIMIT
Overvoltage DC/DC converter warning limit
setting.
R/W
16
‘h42
EEPROM
‘h2266
Y
VOUT_UV_WARN_LIMIT
Undervoltage DC/DC converter warning
limit setting.
R/W
16
‘h43
EEPROM
‘h1D9A
Y
COMMAND FUNCTION
DESCRIPTION
R/W
PAGE
R/W
8
‘h00
OPERATION
Operating mode control.
R/W
8
‘h01
EEPROM
ON_OFF_CONFIG
CONTROL pin and PMBus bus on/off
command setting.
R/W
8
‘h02
CLEAR_FAULTS
CLEAR_FAULTS is used to clear any fault
bits that have been set.
W
0
WRITE_PROTECT
Provides protection against accidental
changes.
R/W
STORE_USER_ALL
Store entire operating memory to
EEPROM.
RESTORE_USER_ALL
2978fa
18
LTC2978
Operation
Summary
DATA
NV
LENGTH COMMAND MEMORY
(BITS) BYTE VALUE
TYPE
DEFAULT
VALUE
PAGED
?
EEPROM
‘h1CCD
Y
‘h45
EEPROM
‘h7F
Y
16
‘h4F
EEPROM
‘hEAA8
N
R/W
8
‘h50
EEPROM
‘hB8
N
Overtemperature warning limit setting.
R/W
16
‘h51
EEPROM
‘hEA58
N
UT_WARN_LIMIT
Undertemperature warn limit setting.
R/W
16
‘h52
EEPROM
‘h8000
N
UT_FAULT_LIMIT
Undertemperature fault limit setting.
R/W
16
‘h53
EEPROM
‘hCD80
N
UT_FAULT_RESPONSE
The UT_FAULT_RESPONSE command
instructs the device on what action to take
in response to an undertemperature fault.
R/W
8
‘h54
EEPROM
‘hB8
N
VIN_OV_FAULT_LIMIT
Input supply overvoltage fault limit setting.
R/W
16
‘h55
EEPROM
‘hD3C0
N
VIN_OV_FAULT_RESPONSE
The VIN_OV_FAULT_RESPONSE command R/W
instructs the device on what action to take
in response to an input overvoltage fault.
8
‘h56
EEPROM
‘h80
N
VIN_OV_WARN_LIMIT
Overvoltage input supply warning limit
setting.
R/W
16
‘h57
EEPROM
‘hD380
N
VIN_UV_WARN_LIMIT
Undervoltage input supply warning limit
setting.
R/W
16
‘h58
EEPROM
‘h8000
N
VIN_UV_FAULT_LIMIT
Undervoltage input supply fault limit
setting.
R/W
16
‘h59
EEPROM
‘h8000
N
VIN_UV_FAULT_RESPONSE
The VIN_UV_FAULT_RESPONSE command R/W
instructs the device on what action to take
in response to an input undervoltage fault.
8
‘h5A
EEPROM
‘h00
N
POWER_GOOD_ON
Output voltage at or above which a power
good should be asserted.
R/W
16
‘h5E
EEPROM
‘h1EB8
Y
POWER_GOOD_OFF
Output voltage at or below which a power
good should be deasserted.
R/W
16
‘h5F
EEPROM
‘h1E14
Y
TON_DELAY
Time, in ms, from CONTROL and/or
Operation on to VOUT_EN on.
R/W
16
‘h60
EEPROM
‘hBA00
Y
TON_RISE
Time, in ms, from when the output starts
to rise until the LTC2978 optionally softconnects its voltage-buffered current DAC
and begins to servo the output voltage to
the desired value.
R/W
16
‘h61
EEPROM
‘hD280
Y
TON_MAX_FAULT_LIMIT
Maximum time, in ms, from VOUT_EN
on assertion that an UV condition will
be tolerated before a TON_MAX_FAULT
condition results.
R/W
16
‘h62
EEPROM
‘hD3C0
Y
TON_MAX_FAULT_RESPONSE
Specifies response to a TON_MAX_FAULT
event.
R/W
8
‘h63
EEPROM
‘hB8
Y
COMMAND FUNCTION
DESCRIPTION
R/W
VOUT_UV_FAULT_LIMIT
Undervoltage DC/DC converter fault limit
R/W
setting. This limit is also used to determine
if Ton_max_fault has been met and the
unit is on.
16
‘h44
VOUT_UV_FAULT_RESPONSE
The VOUT_UV_FAULT_RESPONSE
command instructs the device on
what action to take in response to an
undervoltage fault.
R/W
8
OT_FAULT_LIMIT
Overtemperature fault limit setting.
R/W
OT_FAULT_RESPONSE
The OT_FAULT_RESPONSE command
instructs the device on what action to take
in response to an overtemperature fault.
OT_WARN_LIMIT
2978fa
19
LTC2978
Operation
Summary
COMMAND FUNCTION
DESCRIPTION
R/W
TOFF_DELAY
Time, in ms, from CONTROL and/or
Operation off to VOUT_EN off.
R/W
STATUS_BYTE
Fault status reporting.
STATUS_WORD
The STATUS_WORD command returns
two bytes of information with a summary
of the unit’s fault condition.
STATUS_VOUT
DATA
NV
LENGTH COMMAND MEMORY
(BITS) BYTE VALUE
TYPE
DEFAULT
VALUE
PAGED
?
16
‘h64
EEPROM
‘hBA00
Y
R
8
‘h78
NA
Y
R
16
‘h79
NA
Y
Voltage fault status reporting.
R
8
‘h7A
NA
Y
STATUS_INPUT
The STATUS_INPUT command returns one
byte with status on VIN_SNS.
R
8
‘h7C
NA
N
STATUS_TEMPERATURE
The STATUS_TEMPERATURE command
returns one byte with status information
on temperature.
R
8
‘h7D
NA
N
STATUS_CML
The STATUS_CML command returns
one byte with status information on
communication and memory.
R
8
‘h7E
NA
N
STATUS_MFR_SPECIFIC
The STATUS_MFR_SPECIFIC command
returns one byte with the manufacturer
specific status information.
R
8
‘h80
NA
Y
READ_VIN
Input supply voltage read back.
R
16
‘h88
NA
N
READ_VOUT
DC/DC converter output voltage read back.
R
16
‘h8B
NA
Y
READ_TEMPERATURE_1
Internal junction temperature read back.
R
16
‘h8D
NA
N
PMBUS_REVISION
Read the supported PMBus revision (1.1).
R
8
‘h98
ROM
‘h11
N
MFR_CONFIG
Manufacturer configuration bits that are
channel specific.
R/W
16
‘hD0
EEPROM
‘h0080
Y
MFR_CONFIG_ALL
Manufacturer configuration bits that are
common to all pages.
R/W
8
‘hD1
EEPROM
‘h7B
N
MFR_FAULTBz0_PROPAGATE
Manufacturer configuration that
determines which channel faults are
propagated to FAULTBz0 where z = 0 for
channels 0-3, and z=1 for channels 4-7.
R/W
8
‘hD2
EEPROM
‘h00
Y
MFR_FAULTBz1_PROPAGATE
Manufacturer configuration that
determines which channel faults are
propagated to FAULTBz1.
R/W
8
‘hD3
EEPROM
‘h00
Y
MFR_PWRGD_EN
Maps PWRGD status to the PWRGD pin.
R/W
16
‘hD4
EEPROM
‘h0000
N
MFR_FAULTB00_RESPONSE
Determines response to FAULTB00 pin
being asserted low.
R/W
8
‘hD5
EEPROM
‘h00
N
MFR_FAULTB01_RESPONSE
Determines response to FAULTB01 pin
being asserted low.
R/W
8
‘hD6
EEPROM
‘h00
N
MFR_FAULTB10_RESPONSE
Determines response to FAULTB10 pin
being asserted low.
R/W
8
‘hD7
EEPROM
‘h00
N
MFR_FAULTB11_RESPONSE
Determines response to FAULTB11 pin
being asserted low.
R/W
8
‘hD8
EEPROM
‘h00
N
MFR_VINEN_OV_FAULT_RESPONSE
Determines the response of the VIN_EN
pin to a VOUT_OV_FAULT
R/W
8
‘hD9
EEPROM
‘h00
N
2978fa
20
LTC2978
Operation
Summary
DATA
NV
LENGTH COMMAND MEMORY
(BITS) BYTE VALUE
TYPE
DEFAULT
VALUE
PAGED
?
‘h00
N
EEPROM
‘hF320
N
EEPROM
‘hFB20
N
‘hDD
NA
Y
16
‘hDE
NA
N
R
16
‘hDF
NA
N
Manufacturer register that contains the
code of the 10-bit voltage-buffered current
DAC.
R/W
16
‘hE0
EEPROM
‘h0000
Y
MFR_POWERGOOD_ASSERTION_DELAY
Determines power good output assertion
delay.
R/W
16
‘hE1
EEPROM
‘hEB20
N
MFR_WATCHDOG_T_FIRST
First watchdog timer interval.
R/W
16
‘hE2
EEPROM
‘h8000
N
MFR_WATCHDOG_T
Watchdog timer interval.
R/W
16
‘hE3
EEPROM
‘h8000
N
MFR_PAGE_FF_MASK
Selects which channels respond to global
page commands.
R/W
8
‘hE4
EEPROM
‘hFF
N
MFR_PADS
Returns values detected and driven onto
digital I/O pads.
R
16
‘hE5
N/A
N
MFR_I2C_BASE_ADDRESS
This register determines the base value of
the I2C address byte.
R/W
8
‘hE6
EEPROM
‘h5C
N
MFR_SPECIAL_ID
This register contains the manufacturer
code for identifying the LTC2978.
R
16
‘hE7
EEPROM
‘h0121
N
MFR_SPECIAL_LOT
These registers contain customer
dependent codes that identify the factory
programmed user configuration stored in
EEPROM.
R/W
8
‘hE8
EEPROM
Contact
the
Factory
Y
MFR_VOUT_DISCHARGE_THRESHOLD
Coefficient used to multiply VOUT_
COMMAND in order to determine VOUT
OFF threshold voltage.
R/W
16
‘hE9
EEPROM
‘hC200
Y
MFR_FAULT_LOG_STORE
Command a transfer of the fault log from
RAM to EEPROM. This causes the part to
behave as if a channel has faulted off.
W
0
‘hEA
NA
N
MFR_FAULT_LOG_RESTORE
Command a transfer of the fault log
previously stored in EEPROM back to
RAM.
W
0
‘hEB
NA
N
MFR_FAULT_LOG_CLEAR
Initialize the EEPROM block reserved for
fault logging and clear any previous fault
logging locks.
W
0
‘hEC
NA
N
MFR_FAULT_LOG_STATUS
This command returns one byte with
status information on fault logging.
R
8
‘hED
EEPROM
NA
N
MFR_FAULT_LOG
Fault log. Accessed using a block read.
Returns data in the form last in first out.
R
2048
‘hEE
EEPROM
NA
N
COMMAND FUNCTION
DESCRIPTION
R/W
MFR_VINEN_UV_FAULT_RESPONSE
Determines the response of the VIN_EN
pin to a VOUT_UV_FAULT
R/W
8
‘hDA
EEPROM
MFR_RETRY_DELAY
Sets retry interval during retry mode.
R/W
16
‘hDB
MFR_RESTART_DELAY
Sets delay from actual CONTROL active
edge to virtual CONTROL active edge.
R/W
16
‘hDC
MFR_VOUT_PEAK
Returns the maximum measured value of
VOUT .
R
16
MFR_VIN_PEAK
Returns the maximum measured value of
VIN_SNS.
R
MFR_TEMPERATURE_PEAK
Returns the maximum measured value of
temperature.
MFR_DAC
2978fa
21
LTC2978
Operation
Summary
COMMAND FUNCTION
DESCRIPTION
R/W
MFR_COMMON
Contains manufacturer status bits that are
common across multiple LTC chips.
MFR_SPARE_0
DATA
NV
LENGTH COMMAND MEMORY
(BITS) BYTE VALUE
TYPE
DEFAULT
VALUE
PAGED
?
NA
N
R
8
‘hEF
Scratchpad register.
R/W
16
‘hF7
EEPROM
‘h0000
N
MFR_SPARE_2
Paged scratchpad register.
R/W
16
‘hF9
EEPROM
‘h0000
Y
MFR_VOUT_MIN
Returns the minimum measured value of
VOUT.
R
16
‘hFB
NA
Y
MFR_VIN_MIN
Returns the minimum measured value of
VIN_SNS.
R
16
‘hFC
NA
N
MFR_TEMPERATURE_MIN
Returns the minimum measured junction
temperature value.
R
16
‘hFD
NA
N
Detailed PMBus Command Register
Descriptions
PAGE
The PAGE command provides the ability to configure,
control and monitor multiple outputs on one unit. Setting PAGE = ‘hFF allows PMBus commands that support
global page programming to be written simultaneously. The only commands that support PAGE = ‘hFF are
OPERATION and ON_OFF_CONFIG. See MFR_PAGE_FF_
MASK for additional options. Reading any PMBus register
with PAGE = ‘hFF returns unpredictable data and will trigger
a CML fault.
PAGE Data Contents
BIT(S) SYMBOL PURPOSE
b[7:0] Page Page operation.
‘h00: All PMBus commands address channel/page 0.
‘h01: All PMBus commands address channel/page 1.
•
•
•
‘h07: All PMBus commands address channel/page 7.
‘hXX: All nonspecified values reserved.
‘hFF: PMBus commands that support this global PAGE
write mode will be written simultaneously.
2978fa
22
LTC2978
Operation
OPERATION
The OPERATION command is used to turn the unit on and
off in conjunction with the CONTROLn pin and ON_OFF_
CONFIG. This command register responds to the global
page command. The contents and functions of the data
byte are shown in the following tables.
OPERATION Data Contents When On_Off_Config_Use_PMBus Enables Operation_Control
SYMBOL
Action
Operation_control[1:0]
Operation_margin[1:0]
Operation_fault[1:0]
Reserved (read only)
b[7:6]
b[5:4]
b[3:2]
b[1:0]
Turn off immediately
00
XX
XX
00
Turn on
10
00
XX
00
Margin Low (Ignore Faults and
Warnings)
10
01
01
00
Margin Low
10
01
10
00
Margin High (Ignore Faults and
Warnings
10
10
01
00
10
10
10
00
01
00
XX
00
Sequence off and Margin Low
(Ignore Faults and Warnings)
01
01
01
00
Sequence off and Margin Low
01
01
10
00
Sequence off and Margin High
(Ignore Faults and Warnings)
01
10
01
00
Sequence off and Margin High
01
10
10
00
BITS
Margin High
FUNCTION Sequence off and margin to
nominal
Reserved
All remaining combinations
OPERATION Data Contents When On_Off_Config is Configured Such That OPERATION Command is Not Used to Command Channel On
or Off
SYMBOL
Action
Operation_control[1:0]
Operation_margin[1:0]
Operation_fault[1:0]
Reserved (read only)
b[7:6]
b[5:4]
b[3:2]
b[1:0]
Output at Nominal
00, 01 or 10
00
XX
00
Margin Low (Ignore faults and
Warnings)
00, 01 or 10
01
01
00
Margin Low
00, 01 or 10
01
10
00
Margin High (Ignore Faults and
Warnings
00, 01 or 10
10
01
00
Margin High
00, 01 or 10
10
10
00
BITS
FUNCTION
Reserved
All remaining combinations
2978fa
23
LTC2978
Operation
ON_OFF_CONFIG
The ON_OFF_CONFIG command configures the combination of CONTROLn pin input and PMBus bus commands
needed to turn the LTC2978 on/off, including the power-on
behavior, as shown in the following table. This command
register responds to the global page command.
ON_OFF_CONFIG Data Contents
BITS(S) SYMBOL
b[7:5] Reserved
OPERATION
Don’t care. Always returns 0.
b[4]
On_off_config_controlled_on
Control default autonomous power-up operation.
0: Unit powers up regardless of the CONTROLn pin. Unit always powers up with sequencing. To turn unit on
without sequencing, set TON_DELAY = 0.
1: Unit does not power up unless commanded by the CONTROLn pin and/or the OPERATION command on
the serial bus. If On_off_config[3:2] = 00, the unit never powers up.
b[3]
On_off_config_use_pmbus
Controls how the unit responds to commands received via the serial bus.
0: Unit ignores the Operation_control[1:0].
1: Unit responds to Operation_control[1:0]. Depending on On_off_config_use_control, the unit may also
require the CONTROLn pin to be asserted for the unit to start.
b[2]
On_off_config_use_control
Controls how unit responds to the CONTROLn pin.
0: Unit ignores the CONTROLn pin.
1: Unit requires the CONTROLn pin to be asserted to start the unit. Depending on On_off_config_use_
PMBus the OPERATION command may also be required to instruct the device to start.
b[1]
Reserved
Not supported. Always returns 1.
b[0]
On_off_config_control_fast_off
CONTROLn pin turn off action when commanding the unit to turn off
0: Use the programmed TOFF_DELAY.
1: Turn off the output and stop transferring energy as quickly as possible. The device does not sink current
in order to decrease the output voltage fall time.
2978fa
24
LTC2978
Operation
CLEAR_FAULTS
The CLEAR_FAULTS command is used to clear any status
faults that have been set. This command clears all bits in
all unpaged status registers, and the paged status registers
selected by the current PAGE setting. At the same time,
the device negates (clears, releases) its contribution to
ALERTB.
The CLEAR_FAULTS command does not cause a unit that
has latched off for a fault condition to restart.
If the fault condition is present after the fault status is
cleared, the fault status bit shall be set again and the host
notified by the usual means.
Note: this command register does not respond to the
global page command.
WRITE_PROTECT
The WRITE_PROTECT command provides protection
against accidental programming of the LTC2978 command
registers. All supported commands may have their parameters read, regardless of the WRITE_PROTECT setting.
WRITE_PROTECT Data Contents
BITS(S) SYMBOL
b[7:0]
Write_protect[7:0]
STORE_USER_ALL. No Data Contents. Accessing this
command will store all operating memory commands
with a corresponding EEPROM memory location. It is
recommended that this command not be executed while
a unit is enabled since all monitoring is suspended while
the operating memory is transferred to EEPROM.
RESTORE_USER_ALL. No Data Contents. Accessing
this command will restore all commands from EEPROM
Memory. It is recommend that this command not be
executed while a unit is enabled since all monitoring is
suspended while the EEPROM is transferred to operating
memory, and intermediate values from EEPROM may not
be compatible with the values initially stored in operating
memory.
CAPABILITY
The CAPABILITY command provides a way for a host
system to determine some key capabilities of the LTC2978.
This one byte command is read only.
CAPABILITY Data Contents
BITS(S) SYMBOL
b[7]
Capability_pec
Hard coded to 1 indicating Packet
Error Checking is supported. Reading
the Mfr_config_all_pec_en bit will
indicate whether PEC is currently
required.
b[6]
Capability_scl_max
Hard coded to 1 indicating the
maximum supported bus speed is
400kHz.
b[5]
Capability_smb_alert
Hard coded to 1 indicating this device
does have an ALERTB pin and does
support the SMBus Alert Response
Protocol.
Reserved
X: Always returns 0.
OPERATION
8’b1000_0000: Disable all writes except
to the WRITE_PROTECT, PAGE, and
STORE_USER_ALL commands.
8’b0100_0000: Disable all writes except
to the WRITE_PROTECT, PAGE, STORE_
USER_ALL, OPERATION, MFR_PAGE_
FF_MASK, and CLEAR_FAULTS.
8’b0000_0000: Enable writes to all
commands.
8’bxxxx_xxxx: All other values reserved.
OPERATION
b[4:0]
STORE_USER_ALL and RESTORE_USER_ALL
STORE_USER_ALL, RESTORE_USER_ALL commands
provide access to user nonvolatile EEPROM memory.
Once a command is stored in EEPROM, it will be restored
with explicit restore command or when the part emerges
from power-on reset after power is applied. While either
of these commands is being processed, the device will
NACK I2C writes.
2978fa
25
LTC2978
Operation
VOUT_MODE
Output Voltage Related Commands
The data byte for the VOUT_MODE command is 8 bits
that consists of a three bit format and a five bit exponent.
The three bit format specifies PMBus linear mode for all
output voltage related commands. The five bit exponent
provides the exponent for the mantissa specified in the
data word. The LTC2978 device sets the format at the time
of manufacture. The five bit exponent is read only and is
set to a value of –13 decimal.
Output voltage related commands are calculated as follows except for odd numbered channels configured to
measure current:
Voltage = V[15:0] • 2N
where Voltage is the parameter of interest in volts.
V is a 16-bit unsigned binary integer for all voltages,
(e.g. Margin_high[15:0]);
N = Vout_mode_exponent, is a 5-bit two’s complementary
binary integer with a value hardwired to –13 decimal.
VOUT_COMMAND, VOUT_MAX, VOUT_MARGIN_
HIGH, VOUT_MARGIN_LOW, VOUT_OV_FAULT_LIMIT,
VOUT_OV_WARN_LIMIT, VOUT_UV_WARN_LIMIT,
VOUT_UV_FAULT_LIMIT, POWER_GOOD_ON and
POWER_GOOD_OFF
These commands use the same format and provide various
servo, margining, and supervising limits for a channel’s
output voltage. When odd channels are configured to
measure current, the OV_WARN_LIMIT, UV_WARN_LIMIT,
OV_FAULT_LIMIT and UV_FAULT_LIMIT commands are
not supported.
Data Contents
BIT(S)
SYMBOL
b[15:0] Vout_command[15:0],
Vout_max[15:0],
Vout_margin_high[15:0],
Vout_margin_low[15:0],
OPERATION
These commands relate to
output voltage. The data uses
the linear mode format as
defined by VOUT_MODE:
Vout_mode_parameter is read only.
Vout_ov_warn_limit[15:0],
Vout_mode_type is read only.
Vout_uv_fault_limit[15:0],
V(Symbol) = Y • 2N where
Y = b[15:0] is an unsigned
integer and N = Vout_mode_
parameter is a 5-bit two’s
complement exponent that’s
hardwired to –13 decimal.
Power_good_on[15:0],
Units: V
VOUT_MODE Data Contents
BIT(S) SYMBOL
OPERATION
b[7:5]
Vout_mode_type
Reports linear mode. Hard wired to
3’b000.
b[4:0]
Vout_mode_parameter Linear mode exponent. 5-bit two’s
complement integer. Hardwired to
‘h13 (–13 decimal).
Vout_ov_fault_limit[15:0],
Vout_uv_warn_limit[15:0],
Power_good_off[15:0]
2978fa
26
LTC2978
Operation
Input Voltage Related Commands
VIN_ON, VIN_OFF, VIN_OV_FAULT_LIMIT, VIN_OV_
WARN_LIMIT, VIN_UV_WARN_LIMIT and VIN_UV_
FAULT_LIMIT
These commands use the same format and provide voltage
supervising limits for VIN.
Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Vin_on[15:0],
These commands relate to input
voltage. The data uses the linear
format:
Vin_off[15:0],
Vin_ov_fault_limit[15:0],
Vin_ov_warn_limit[15:0],
Vin_uv_warn_limit[15:0],
Vin_uv_fault_limit[15:0]
V(Symbol) = Y • 2N
where N = b[15:11] is a 5-bit
two’s complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Units: V.
Temperature Related Commands
OT_FAULT_LIMIT, OT_WARN_LIMIT, UT_WARN_LIMIT
and UT_FAULT_LIMIT
These commands provide supervising limits for temperature.
Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Ot_fault_limit[15:0],
The data uses the linear format:
Ot_warn_limit[15:0],
T(Symbol) = Y • 2N
Ut_warn_limit[15:0],
where N = b[15:11] is a 5-bit two’s
complement integer and
Ut_fault_limit[15:0]
Y = b[10:0] is an 11-bit two’s
complement integer
Units: °C.
TON_DELAY is the amount time in ms that elapses after
the channel has been allowed on (usually due to CONTROLn pin or OPERATION command) until the channel
enables the power supply. This delay is counted using
SHARE_CLK only.
TON_RISE is the amount of time in ms that elapses after
the power supply has been enabled until the LTC2978’s
voltage buffered current DAC soft connects and servo’s
the output voltage to the desired level if Mfr_dac_mode =
2’b00. This delay is counted using SHARE_CLK only.
TON_MAX_FAULT_LIMIT is the maximum amount of time
that can elapse after the power supply has been enabled
until the LTC2978 unmasks the VOUT_UV_FAULT_LIMIT
threshold. (Note that a value of zero means there is no limit
to how long the power supply can attempt to bring up its
output voltage.) This delay is counted using SHARE_CLK
only.
TOFF_DELAY is the amount of time that elapses after the
CONTROLn pin and/or OPERATION command is deasserted until the channel is disabled (soft-off). This delay
is counted using SHARE_CLK if available, otherwise the
internal oscillator is used.
Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Ton_delay[15:0],
The data uses the linear format:
Ton_rise[15:0],
T(Symbol) = Y • 2N
Ton_max_fault_limit[15:0], Where N = b[15:11] is a 5-bit
two’s complement integer and
Toff_delay[15:0],
Y = b[10:0] is an 11-bit two’s
complement integer
The internal timers operate
on a 10µs internal clock. The
SHARE_CLK pin may be used to
synchronize the 10µs timer.
Timer Limits
Delays are rounded to the nearest
10µs
TON_DELAY, TON_RISE, TON_MAX_FAULT_LIMIT and
TOFF_DELAY
Units: ms. Max value: 655ms
These commands share the same format and provide
sequencing and timer fault and warning delays in ms.
2978fa
27
LTC2978
Operation
Fault Response for Voltages Measured by the High
Speed Supervisor
• Set the appropriate bit(s) in the STATUS_BYTE
VOUT_OV_FAULT_RESPONSE and VOUT_UV_FAULT_
RESPONSE
• Set the appropriate bit in the corresponding STATUS_
VOUT register, and
The fault response documented here is for voltages that
are measured by the high speed supervisor. These voltages
are measured over a short period of time and may require
a de-glitch period. Note that in addition to the response
described by these commands, the LTC2978 will also:
• Notify the host by pulling the ALERTB pin low.
• Set the appropriate bit(s) in the STATUS_WORD
Note: Odd numbered channels configured for high resolution ADC measurements will not respond to OV/UV faults
or warnings.
Data Contents
BIT(S) SYMBOL
OPERATION
b[7:6] Vout_ov_fault_response_action,
Response action.
Vout_uv_fault_response_action
2’b00: The unit continues operation without interruption.
2’b01: The unit continues operating for the delay time specified by bits[2:0] in increments of Ts_vs.
If the fault is still present at the end of the delay time, the unit responds as programmed in the retry
setting (bits [5:3]).
2’b1X: The device shuts down and responds according to the retry setting in bits [5:3].
b[5:3] Vout_ov_fault_response_retry,
Vout_uv_fault_response_retry
Response action:
3’b000: A zero value for the retry setting means that the unit does not attempt to restart. The output remains
disabled until the fault is cleared.
3’b001-111: The PMBus device attempts to restart continuously, without limitation, using Mfr_retry_delay,
until it is commanded OFF (by the CONTROL pin or OPERATION command or both), bias power is removed,
or another fault condition causes the unit to shut down.
b[2:0] Vout_ov_fault_response_delay,
Vout_uv_fault_response_delay
This sample count determines the amount of time a unit is to ignore a fault after it is first detected. Use this
delay to de-glitch fast faults.
3’b000: The unit turns off immediately.
3’b001 – 3’b111: The unit turns off after b[2:0] samples at the sampling period of Ts_vs (12.2µs typical).
2978fa
28
LTC2978
Operation
Fault Response for Values Measured by the ADC
• Set the appropriate bit(s) in the STATUS_BYTE
OT_FAULT_RESPONSE, UT_FAULT_RESPONSE,
VIN_OV_FAULT_RESPONSE and VIN_UV_FAULT_
RESPONSE
• Set the appropriate bit(s) in the STATUS_WORD
The fault response documented here is for values that are
measured by the ADC. These values are measured over a
longer period of time and are not de-glitched. Note that in
addition to the response described by these commands,
the LTC2978 will also:
• Notify the host by pulling the ALERTB pin low.
• Set the appropriate bit in the corresponding STATUS_VIN
or STATUS_TEMPERATURE register, and
Data Contents
BIT(S) SYMBOL
OPERATION
b[7:6] Ot_fault_response_action,
Response action:
Ut_fault_response_action,
2’b00: The unit continues operation without interruption.
Vin_ov_fault_response_action,
2’b01: The device shuts down and responds according to the retry setting in bits [5:3].
Vin_uv_fault_response_action
2’b10: The device shuts down and responds according to the retry setting in bits [5:3].
2’b11: The device shuts down and responds according to the retry setting in bits [5:3].
b[5:3] Ot_fault_response_retry,
Ut_fault_response_retry,
Vin_ov_fault_response_retry,
Vin_uv_fault_response_retry
b[2:0] Ot_fault_response_delay,
Response action:
3’b000: A zero value for the retry setting means that the unit does not attempt to restart. The output remains
disabled until the fault is cleared.
3’b001-111: The PMBus device attempts to restart continuously, without limitation, using Mfr_retry_delay,
until it is commanded OFF (by the CONTROLn pin or OPERATION command or both), bias power is removed,
or another fault condition causes the unit to shut down.
Hard coded to 3’b000. The unit turns off immediately.
Ut_fault_response_delay,
Vin_ov_fault_response_delay,
Vin_uv_fault_response_delay
2978fa
29
LTC2978
Operation
Timed Fault Response
The device also:
TON_MAX_FAULT_RESPONSE
• Sets the HIGH_BYTE bit in the STATUS_BYTE,
This command defines the LTC2978 response to a
TON_MAX_FAULT. At start-up, the TON_MAX_FAULT_
RESPONSE is disarmed once the output voltage reaches
the VOUT_UNDER_VOLTAGE_LIMIT. The only way to
protect against a short-circuited output at start-up is
to take action in response to a TON_MAX_FAULT since
VOUT_UV_FAULT_RESPONSE is not armed until the output
reaches the VOUT_UNDER_VOLTAGE_LIMIT.
• Sets the VOUT bit in the STATUS_WORD,
• Sets the TON_MAX_FAULT bit in the STATUS_VOUT
register, and
• Notifies the host by asserting ALERTB.
TON_MAX_FAULT_RESPONSE Data Contents
BIT(S) SYMBOL
OPERATION
b[7:6] Ton_max_fault_response_action
Response action.
2’b00: The unit continues operation without interruption.
2’b01: The unit continues operating for the delay time specified which for this type of fault corresponds to an
immediate shutdown. After shutting off, the device responds according to the retry settings in bits [5:3].
2’b1X: The device shuts down and responds according to the retry setting in bits [5:3].
b[5:3] Ton_max_fault_response_retry
Response action:
3’b000: A zero value for the Retry Setting means that the unit does not attempt to restart. The output remains
disabled until the fault is cleared.
3’b001-111: The PMBus device attempts to restart continuously, without limitation, using Mfr_retry_delay,
until it is commanded OFF (by the CONTROLn pin or OPERATION command or both), bias power is removed,
or another fault condition causes the unit to shut down.
b[2:0] Ton_max_fault_response_delay
Hard coded to 3’b000. The unit turns off immediately.
2978fa
30
LTC2978
Operation
STATUS_BYTE:
STATUS_WORD Data Contents
The STATUS_BYTE command returns the summary of the
most critical faults or warnings which have occurred, as
shown in the following table:
BIT(S) SYMBOL
OPERATION
b[15] Status_word_vout
An output voltage fault or
warning has occurred.
b[14] Status_word_iout
Not supported. Always returns 0.
STATUS_BYTE Data Contents
b[13] Status_word_input
An input voltage fault or
warning has occurred.
b[12] Status_word_mfr
A manufacturer specific fault
has occurred.
BIT(S) SYMBOL
OPERATION
b[7]
Status_byte_busy
Device busy when PMBus command
received.
b[6]
Status_byte_off
This bit is asserted if the unit is
not providing power to the output,
regardless of the reason, including
simply not being enabled.
b[11] Status_word_power_not_good The POWER_GOOD signal, if
present is negated. Power is
not good.
b[10] Status_word_cooling
Not supported. Always returns 0.
b[5]
Status_byte_vout_ov
An output overvoltage fault has
occurred.
b[9]
Status_word_other
Not supported. Always returns 0.
b[8]
Status_word_unknown
Not supported. Always returns 0.
b[4]
Status_byte_iout_oc
Not supported. Always returns 0.
b[7]
Status_word_busy
b[3]
Status_byte_vin_uv
A VIN undervoltage fault has occurred.
Device busy when PMBus
command received.
b[2]
Status_byte_temp
A temperature fault or warning has
occurred.
b[6]
Status_word_off
Status_byte_off
b[5]
Status_word_vout_ov
Status_byte_vout_ov
b[1]
Status_byte_cml
A communication, memory or logic
fault has occurred.
b[4]
Status_word_iout_oc
Not supported. Always returns 0.
b[3]
Status_word_vin_uv
Status_byte_vin_uv
b[2]
Status_word_temp
Status_byte_temp
b[1]
Status_word_cml
Status_byte_cml
b[0]
Status_word_high_byte
A bit in the high byte of the
STATUS_WORD (b[15:8]) is
set.
b[0]
Status_byte_high_byte
Fault/warning not listed in b[7:1].
STATUS_WORD:
The STATUS_WORD command returns two bytes of information with a summary of the unit’s fault condition. Based
on the information in these bytes, the host can get more
information by reading the appropriate status byte.
The low byte of the STATUS_WORD is the same register
as the STATUS_BYTE command.
2978fa
31
LTC2978
Operation
STATUS_VOUT
STATUS_TEMPERATURE
The STATUS_VOUT command returns the summary of
the voltage faults or warnings which have occurred, as
shown in the following table:
The STATUS_TEMPERATURE command returns the summary of the temperature faults or warnings which have
occurred, as shown in the following table:
STATUS_VOUT Data Contents
STATUS_TEMPERATURE Data Contents
BIT(S) SYMBOL
OPERATION
Bit(s) Symbol
Operation
b[7]
Status_vout_ov_fault
Overvoltage fault.
b[7]
Status_temperature_ot_fault
Overtemperature fault.
b[6]
Status_vout_ov_warn
Overvoltage warning.
b[6]
Status_temperature_ot_warn
Overtemperature warning.
b[5]
Status_vout_uv_warn
Undervoltage warning
b[5]
Status_temperature_ut_warn
Undertemperature warning.
b[4]
Status_vout_uv_fault
Undervoltage fault.
b[4]
Status_temperature_ut_fault
Undertemperature fault.
b[3]
Status_vout_max_fault
VOUT_MAX fault. An attempt
has been made to set the output
voltage to a value higher than
allowed by the VOUT_MAX
command.
b[3]
Reserved
Reserved. Always returns 0.
b[2]
Reserved
Reserved. Always returns 0.
b[1]
Reserved
Reserved. Always returns 0.
b[0]
Reserved
Reserved. Always returns 0.
b[2]
Status_vout_ton_max_fault
TON_MAX_FAULT sequencing
fault.
b[1]
Status_vout_toff_max_warn Not supported. Always returns 0.
b[0]
Status_vout_tracking_error
Not supported. Always returns 0.
STATUS_INPUT
The STATUS_INPUT command returns the summary of
the VIN faults or warnings which have occurred, as shown
in the following table:
STATUS_CML
The STATUS_CML command returns the summary of the
communication, memory and logic faults or warnings
which have occurred, as shown in the following table:
STATUS_CML Data Contents
BIT(S) SYMBOL
b[7]
Status_cml_cmd_fault
STATUS_INPUT Data Contents
BIT(S) SYMBOL
OPERATION
b[7]
Status_input_ov_fault
VIN Overvoltage fault
b[6]
Status_input_ov_warn
VIN Overvoltage warning
b[5]
Status_input_uv_warn
VIN Undervoltage warning
b[4]
Status_input_uv_fault
VIN Undervoltage fault
b[3]
Status_input_off
Unit is off for insufficient input voltage.
b[2]
IIN overcurrent fault
Not supported. Always returns 0.
b[1]
IIN overcurrent warn
Not supported. Always returns 0.
b[0]
PIN overpower warn
Not supported. Always returns 0.
OPERATION
1 = An illegal or unsupported
command fault has occurred.
0 = No fault has occurred.
b[6]
Status_cml_data_fault
b[5]
Status_cml_pec_fault
b[4]
Status_cml_memory_fault
1 = Illegal or unsupported data
received.
0 = No fault has occurred.
1 = A PEC fault has occurred.
0 = No fault has occurred.
1 = A fault has occurred in the
NVM.
0 = No fault has occurred.
b[3]
Status_cml_processor_fault Not supported, always returns 0.
b[2]
Reserved
Not supported, always returns 0.
b[1]
Status_cml_PMBus_fault
1 = A communication fault other
than ones listed in this table has
occurred.
b[0]
Status_cml_unknown_fault
0 = No fault has occurred.
Not supported, always returns 0.
2978fa
32
LTC2978
Operation
STATUS_MFR_SPECIFIC
The STATUS_MFR_SPECIFIC command returns manufacturer specific status flags. Bits marked FAULT = No are
intended to support polled handshaking; these are not
latched nor do they assert ALERTB. Bits marked Channel
= All can be read from any page. Bits marked FAULT = Yes
assert ALERTB low and are cleared by CLEAR_FAULTS.
STATUS_MFR_SPECIFIC Data Contents
BIT(S) SYMBOL
CHANNEL
FAULT
b[7]
Status_mfr_discharge
OPERATION
1 = A VOUT discharge fault occurred while attempting to enter the ON state
0 = No VOUT discharge fault has occurred
Current Page
Yes
b[6]
Status_mfr_fault1_in
This channel attempted to turn on while the FAULTBz1 pin was asserted low, Current Page
or this channel has shut down at least once in response to a FAULTBz1 pin
asserting low since the last CONTROLn pin toggle, OPERATION command
ON/OFF cycle or CLEAR_FAULTS command.
Yes
b[5]
Status_mfr_fault0_in
This channel attempted to turn on while the FAULTBz0 pin was asserted low, Current Page
or this channel has shut down at least once in response to a FAULTBz0 pin
asserting low since the last CONTROLn pin toggle, OPERATION command
ON/OFF cycle or CLEAR_FAULTS command.
Yes
b[4]
Status_mfr_servo_target_reached
Servo target has been reached.
Current Page
No
b[3]
Status_mfr_dac_connected
DAC is connected and driving VDACP pin.
Current Page
No
b[2]
Status_mfr_dac_saturated
A previous servo operation terminated with maximum or minimum DAC
value.
Current Page
Yes
b[1]
Status_mfr_vinen_faulted_off
VIN_EN has been deasserted due to a VOUT fault.
All
No
b[0]
Status_mfr_watchdog_fault
1 = A watchdog fault has occurred.
0 = No watchdog fault has occurred.
All
Yes
2978fa
33
LTC2978
Operation
ADC Monitoring Commands
READ_VIN
This command returns the most recent ADC measured
value of the voltage measured at the VIN_SNS pin.
READ_VIN Data Contents
BIT(S) SYMBOL
READ_TEMPERATURE_1
This command returns the most recent ADC measured
value of junction temperature in °C as determined by the
LTC2978’s internal temperature sensor.
READ_TEMPERATURE_1 Data Contents
BIT(S) SYMBOL
OPERATION
OPERATION
b[15:0] Read_temperature_1 [15:0] The data uses the linear format:
Temp(Symbol) = Y • 2N
b[15:0] Read_vin[15:0] The data uses the linear format:
V(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit
two’s complement integer and
where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Y = b[10:0] is an 11-bit two’s complement
integer
Units: V
READ_VOUT
This command returns the most recent ADC measured
value of the channel’s output voltage. When odd channels
are configured to measure current, the data contents have
a slightly modified meaning, as described in the second
table below.
READ_VOUT Data Contents
BIT(S) SYMBOL
OPERATION
Units: °C.
PMBUS_REVISION
The PMBUS_REVISION command register is read only and
reports the LTC2978 compliance to the PMBus standard
revision 1.1.
PMBUS_REVISION Data Contents
BIT(S) SYMBOL
OPERATION
b[7:0] PMBus_rev
Reports the PMBus standard revision
compliance. This is hard-coded to ‘h11 for
revision 1.1.
b[15:0] Read_vout[15:0] The data uses the linear mode format as
defined by VOUT_MODE:
V(Read_vout) = Y • 2N where Y = b[15:0] is
an unsigned integer and N = Vout_mode_
parameter is a 5-bit two’s complement
exponent that’s hardwired to –13 decimal.
Units: V.
READ_VOUT Data Contents—for Odd Channels Configured to
Measure Current
Bit(s)
Symbol
Operation
b[15:0] Read_vout[15:0] The data uses the linear format:
V(Symbol) = Y • 2N
where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s complement
integer
Units: mV
2978fa
34
LTC2978
Operation
Manufacturer Specific Commands
MFR_CONFIG:
This command is used to configure various manufacturer
specific operating parameters for each channel.
MFR_CONFIG Data Contents
BIT(S) SYMBOL
b[15:12] Reserved
b[11] Mfr_config_fast_servo_off
b[10]
b[9]
b[8]
b[7]
b[6]
b[5:4]
b[3]
b[2]
b[1]
b[0]
OPERATION
Don’t care. Always returns 0.
Disables fast servo when margining or trimming output voltages:
0: fast-servo enabled.
1: fast-servo disabled.
Mfr_config_supervisor_resolution Selects supervisor resolution:
0: high resolution – 4mV/LSB, range for VSENSEP is 0V to 3.8V.
1: low resolution – 8mV/LSB, range for VSENSEP is 0V to 6.0V.
Mfr_config_adc_hires
Selects ADC resolution for odd channels. Ignored for even channels (they always use low res).
0: low resolution – 122µV/LSB.
1: high resolution – 15.6µV/LSB.
Mfr_config_controln_sel
Selects the active control pin input (CONTROL0 or CONTROL1) for this channel.
0: Select CONTROL0 pin.
1: Select CONTROL1 pin.
Mfr_config_servo_continuous
Select whether the UNIT should continuously servo VOUT after it has reached a new margin or nominal
target. Only applies when Mfr_dac_mode = 2’b00.
0: Do not continuously servo VOUT after reaching initial target.
1: Continuously servo VOUT to target.
Mfr_config_servo_on_warn
Control re-servo on warning feature. Only applies when Mfr_config_dac_mode = 2’b00 and
Mfr_config_servo_continuous = 0.
0: Do not allow the unit to re-servo when a VOUT warning threshold is met or exceeded.
1: Allow the unit to re-servo VOUT to nominal target if
VOUT ≥ V(Vout_ov_warn_limit) or
VOUT ≤ V(Vout_uv_warn_limit).
Mfr_config_dac_mode
Determines how DAC is used when channel enters ON state or is already in ON state.
00: Soft connect (if needed) and servo to target. Wait for TON_RISE if just entering ON state.
01: DAC not connected.
10: DAC connected using value from MFR_DAC command. Does not wait for TON_RISE if just entering ON state.
11: DAC is soft connected. After soft connect is complete MFR_DAC may be written.
Mfr_config_vo_en_wpu_en
VO_EN charge pumped, current-limited pull-up enable.
0: Disable weak pull-up. VO_EN driver is three-stated when channel is on.
1: Use weak current-limited pull-up on VO_EN when the channel is on.
For channels 4-7 this bit is treated as a 0 regardless of its value.
Mfr_config_vo_en_wpd_en
VO_EN current-limited pull-down enable.
0: Use a fast N-channel device to pull down VO_EN when the channel is off for any reason.
1: Use weak current-limited pull-down to discharge VO_EN when channel is off due to soft stop by the CONTROLn
pin and/or OPERATION command. If the channel is off due to a fault, use the fast pull-down on VO_EN.
For channels 4-7 this bit is treated as a 0 regardless of its value.
Mfr_config_dac_gain
DAC buffer gain.
0: Select DAC buffer gain dac_gain_0 (1.38V full-scale)
1: Select DAC buffer gain dac_gain_1 (2.65V full-scale)
Mfr_config_dac_pol
DAC output polarity.
0: Encodes negative (inverting) DC/DC converter trim input.
1: Encodes positive (noninverting) DC/DC converter trim input.
2978fa
35
LTC2978
Operation
MFR_CONFIG_ALL:
This command is used to configure parameters that are
common to all channels on the IC. They may be set or
reviewed from any PAGE setting.
MFR_CONFIG_ALL Data Contents
MFR_CONFIG_ALL Data Contents
BIT(S) SYMBOL
b[7]
Mfr_config_fault_log_enable
b[6]
Mfr_vin_on_clr_faults_en
b[5]
Mfr_config_control1_pol
b[4]
Mfr_config_control0_pol
OPERATION
Enable fault logging to NVM in
response to Fault.
0: Fault logging to NVM is
disabled
1: Fault logging to NVM is
enabled
VIN_ON rising edge to clear all
latched faults
0: VIN_ON clear faults feature is
disabled
1: VIN_ON clear faults feature is
enabled
Selects active polarity of
control1 pin.
0: Active low (pull pin low to
start unit)
1: Active high (pull pin high to
start unit)
Selects active polarity of
control0 pin.
0: Active low (pull pin low to
start unit)
1: Active high (pull pin high to
start unit)
b[3]
b[2]
b[1]
b[0]
Mfr_config_vin_share_enable Allow this unit to hold shareclock pin low when VIN_ON
has fallen below VIN_OFF. When
enabled, this unit will also turn
all channels off in response to
share-clock being held low.
0: Share-clock inhibit is disabled
1: Share-clock inhibit is enabled
Mfr_config_all_pec_en
PMBus packet error checking
enable.
0: PEC is accepted but not
required
1: PEC is required
Mfr_config_all_longer_
Increase PMBus timeout internal
pmbus_timeout
by a factor of 8.
0: PMBus timeout is not
multiplied by a factor of 8
1: PMBus timeout is multiplied
by a factor of 8
Mfr_config_all_vinen_wpu_
VIN_EN charge pumped, currentdis
limited pull-up disable.
0: Use weak current-limited pullup on VIN_EN after power-up, as
long as no faults have forced
VIN_EN off.
1: Disable weak pull-up. VIN_EN
driver is three-stated after
power-up as long as no faults
have forced VIN_EN off.
2978fa
36
LTC2978
Operation
MFR_FAULTB00_PROPAGATE, MFR_FAULTB01_
PROPAGATE, MFR_FAULTB10_PROPAGATE and
MFR_FAULTB11_PROPAGATE
These manufacturer specific commands enable channels
that have faulted off to propagate that state to the appropriate fault pin. There are two zones in the LTC2978.
In zone 0, faulted off states for channels 0 through 3 can
be propagated to FAULT00 or FAULT01. In zone 1, faulted
off states for channels 4 through 7 can be propagated to
FAULT10 or FAULT11. See Figure 13.
MFR_FAULTB00_PROPAGATE Data Contents—Fault Zone 0
(Pages 0-3)
BIT(S) SYMBOL
OPERATION
b[7:1] Reserved
Don’t care. Always returns 0.
b[0]
Enable fault propagation.
0: FAULTB00 will not be affected if
a fault is declared.
1: FAULTB00 will be asserted low
if a fault is declared.
Mfr_faultb00_propagate
MFR_FAULTB10_PROPAGATE Data Contents—Fault Zone 1
(Pages 4-7)
BIT(S) SYMBOL
OPERATION
b[7:1] Reserved
Don’t care. Always returns 0.
b[0]
Enable fault propagation.
0: FAULTB10 will not be affected if
a fault is declared.
1: FAULTB10 will be asserted low
if a fault is declared.
Mfr_faultb10_propagate
MFR_FAULTB11_PROPAGATE Data Contents—Fault Zone 1
(Pages 4-7)
BIT(S) SYMBOL
OPERATION
b[7:1] Reserved
Don’t care. Always returns 0.
b[0]
Enable fault propagation.
0: FAULTB11 will not be affected if
a fault is declared.
1: FAULTB11 will be asserted low
if a fault is declared.
Mfr_faultb11_propagate
MFR_FAULTB01_PROPAGATE Data Contents—Fault Zone 0
(Pages 0-3)
BIT(S) SYMBOL
OPERATION
b[7:1] Reserved
Don’t care. Always returns 0.
b[0]
Enable fault propagation.
0: FAULTB01 will not be affected if
a fault is declared.
1: FAULTB01 will be asserted low
if a fault is declared.
Mfr_faultb01_propagate
2978fa
37
LTC2978
Operation
MFR_PWRGD_EN
This command register controls the mapping of power
good status to the power good pin. Note that odd numbered channels whose ADC is in high res mode do not
contribute to power good.
MFR_PWRGD_EN Data Contents
BIT(S) SYMBOL
OPERATION
b[15:9] Reserved
Read only, always returns 0s.
b[8]
Mfr_pwrgd_en_wdog
Watchdog
1 = Watchdog timer not-expired status is ANDed with PWRGD status for any similarly enabled channels to
determine when the PWRGD pin gets asserted.
0 = Watchdog timer does not affect the PWRGD pin.
b[7]
Mfr_pwrgd_en_chan7
Channel 7
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[6]
Mfr_pwrgd_en_chan6
Channel 6
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[5]
Mfr_pwrgd_en_chan5
Channel 5
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[4]
Mfr_pwrgd_en_chan4
Channel 4
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[3]
Mfr_pwrgd_en_chan3
Channel 3
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[2]
Mfr_pwrgd_en_chan2
Channel 2
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[1]
Mfr_pwrgd_en_chan1
Channel 1
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
b[0]
Mfr_pwrgd_en_chan0
Channel 0
1 = PWRGD status for this channel is ANDed with PWRGD status for any similarly enabled channels to determine
when the PWRGD pin gets asserted.
0 = PRWGD status for this channel does not affect the PWRGD pin.
2978fa
38
LTC2978
Operation
MFR_FAULTB00_RESPONSE, MFR_FAULTB01_
RESPONSE, MFR_FAULTB10_RESPONSE and MFR_
FAULTB11_RESPONSE
These manufacturer specific commands share the same
format and specify the response to assertions of the bidirectional fault pins. For fault zone 0, MFR_FAULTB00_RESPONSE determines how channels 0-3 respond when
the FAULTB00 pin is asserted, and MFR_FAULTB01_
RESPONSE determines how channels 0-3 respond
when the FAULTB01 pin is asserted. For fault zone 1,
MFR_FAULTB10_RESPONSE determines how channels
4-7 respond when the FAULTB10 pin is asserted, and
MFR_FAULTB11_RESPONSE determines how channels
4-7 respond when the FAULTB11 pin is asserted. If one
or more bits in the MFR_FAULTBzn_RESPONSE registers
are set, a FAULTBzn assertion will cause the ALERTB pin to
assert low and set the appropriate bit in the STATUS_MFR_
SPECIFIC register.
Data Contents—Fault Zone 0 Response Commands
BIT(S) SYMBOL
b[7:4] Reserved
b[3] Mfr_faultb00_response_chan3,
Mfr_faultb01_response_chan3
b[2]
Mfr_faultb00_response_chan2,
Mfr_faultb01_response_chan2
b[1]
Mfr_faultb00_response_chan1,
Mfr_faultb01_response_chan1
b[0]
Mfr_faultb00_response_chan0,
Mfr_faultb01_response_chan0
OPERATION
Read only, always returns 0s.
Channel 3 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 2 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 1 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 0 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Data Contents—Fault Zone 1 Response Commands
BIT(S) SYMBOL
b[7:4] Reserved
b[3] Mfr_faultb10_response_chan7,
Mfr_faultb11_response_chan7
b[2]
Mfr_faultb10_response_chan6,
Mfr_faultb11_response_chan6
b[1]
Mfr_faultb10_response_chan5,
Mfr_faultb11_response_chan5
b[0]
Mfr_faultb10_response_chan4,
Mfr_faultb11_response_chan4
OPERATION
Read only, always returns 0s.
Channel 7 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 6 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 5 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
Channel 4 response.
0: The channel continues operation without interruption.
1: The channel shuts down if the corresponding FAULTBzn pin is still asserted after 10µs. When the FAULTBzn
pin subsequently deasserts, the channel turns back on, honoring TON_DELAY and TON_RISE settings.
2978fa
39
LTC2978
Operation
MFR_VINEN_OV_FAULT_RESPONSE
This command register determines whether VOUT over
voltage faults from a given channel cause the VIN_EN pin
to be forced off.
MFR_VINEN_OV_FAULT_RESPONSE Data Contents
BIT(S)
b[7]
SYMBOL
OPERATION
Mfr_vinen_ov_fault_response_chan7
Response to channel 7 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[6]
Mfr_vinen_ov_fault_response_chan6
Response to channel 6 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[5]
Mfr_vinen_ov_fault_response_chan5
Response to channel 5 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[4]
Mfr_vinen_ov_fault_response_chan4
Response to channel 4 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[3]
Mfr_vinen_ov_fault_response_chan3
Response to channel 3 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[2]
Mfr_vinen_ov_fault_response_chan2
Response to channel 2 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[1]
Mfr_vinen_ov_fault_response_chan1
Response to channel 1 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[0]
Mfr_vinen_ov_fault_response_chan0
Response to channel 0 VOUT_OV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
2978fa
40
LTC2978
Operation
MFR_VINEN_UV_FAULT_RESPONSE
This command register determines whether VOUT under
voltage faults from a given channel cause the VIN_EN pin
to be forced off.
MFR_VINEN_UV_FAULT_RESPONSE Data Contents
BIT(S)
b[7]
SYMBOL
OPERATION
Mfr_vinen_uv_fault_response_chan7
Response to channel 7 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[6]
Mfr_vinen_uv_fault_response_chan6
Response to channel 6 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[5]
Mfr_vinen_uv_fault_response_chan5
Response to channel 5 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[4]
Mfr_vinen_uv_fault_response_chan4
Response to channel 4 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[3]
Mfr_vinen_uv_fault_response_chan3
Response to channel 3 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[2]
Mfr_vinen_uv_fault_response_chan2
Response to channel 2 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[1]
Mfr_vinen_uv_fault_response_chan1
Response to channel 1 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
b[0]
Mfr_vinen_uv_fault_response_chan0
Response to channel 0 VOUT_UV_FAULT.
1 = Disable VIN_EN via fast pull-down.
0 = Leave VIN_EN as-is.
2978fa
41
LTC2978
Operation
MFR_RETRY_DELAY
MFR_VOUT_PEAK
This command determines the retry interval when the
LTC2978 is in hiccup mode in response to a fault condition.
This command returns the maximum ADC measured value
of the channel’s output voltage. This command is not supported for odd channels that are configured to measure
current. This register is reset to zero when the LTC2978
emerges from power-on reset or when a CLEAR_FAULTS
command is executed.
MFR_RETRY_DELAY Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_retry_delay The data uses the linear format:
T(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s complement
integer
This delay is counted using SHARE_CLK
only.
MFR_VOUT_PEAK Data Contents
BIT(S) SYMBOL
b[15:0] Mfr_vout_peak[15:0] The data uses the linear mode format as
defined by VOUT_MODE:
V(mfr_vout_peak) = Y • 2N where Y =
b[15:0] is an unsigned integer and N =
Vout_mode_parameter is a 5-bit two’s
complement exponent that’s hardwired
to –13 decimal.
Delays are rounded to the nearest 200µs.
Units: ms. Max delay is 13.1 sec.
Units: V.
MFR_RESTART_DELAY
This command determines how the CONTROLn pins are
adjusted before use. The time the adjusted version of the
CONTROLn pin is in the off polarity is stretched by this command to be at least Mfr_restart_delay ms. CONTROLn pin
transitions whose OFF time exceeds Mfr_restart_delay are
not affected by this command. A value of all zeros disables
this feature.
MFR_RESTART_DELAY Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_restart_delay The data uses the linear format:
T(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s complement
integer
OPERATION
MFR_VIN_PEAK
This command returns the maximum ADC measured value
of the input voltage. The contents of this register are reset
to ‘h7C00 when the LTC2978 emerges from power-on reset
or when a CLEAR_FAULTS command is executed.
MFR_VIN_PEAK Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_vin_peak[15:0] The data uses the linear format:
V(Symbol) = Y • 2N
where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Units: V
This delay is counted using SHARE_CLK
only.
MFR_TEMPERATURE_PEAK
Delays are rounded to the nearest 200µs.
This command returns the maximum ADC measured
value of junction temperature in °C as determined by
the LTC2978’s internal temperature sensor. The contents
Units: ms. Max delay is 13.1 sec.
2978fa
42
LTC2978
Operation
of this register are reset to ‘h7C00 when the LTC2978
emerges from power-on reset or when a CLEAR_FAULTS
command is executed.
MFR_TEMPERATURE_PEAK Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_temperature_peak[15:0] The data uses the linear format:
V(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit
two’s complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Units: °C.
MFR_DAC
This command register returns the 10-bit value for the
voltage-buffered current DAC. This register may be written when Mfr_config_dac_mode is configured for either
of the two manual DAC modes.
MFR_DAC Data Contents
BIT(S)
SYMBOL
b[15:10] Reserved
b[9:0]
OPERATION
Read only, always returns ‘h3F.
Mfr_dac_direct_val Voltage-buffered current DAC code value.
MFR_POWERGOOD_ASSERTION_DELAY
This command register allows the user to program the
delay from when the internal power good signal becomes
valid until the power good output is asserted.
MFR_POWERGOOD_ASSERTION_DELAY Data Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_powergood_assertion_delay The data uses the linear format:
T(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit
two’s complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer.
MFR_WATCHDOG_T_FIRST and MFR_WATCHDOG_T
The MFR_WATCHDOG_T_FIRST register allows the user to
program the duration of the first watchdog timer interval
following assertion of the POWER GOOD signal, assuming
the POWER GOOD signal reflects the status of the watchdog
timer. If assertion of POWER GOOD is not conditioned by the
watchdog timer’s status, then MFR_WATCHDOG_T_FIRST
applies to the first timing interval after the timer is enabled.
Writing a value of 0ms to the MFR_WATCHDOG_T_FIRST
register disables the watchdog timer.
The MFR_WATCHDOG_T register allows the user to
program watchdog time intervals subsequent to the
MFR_WATCHDOG_T_FIRST timing interval. Writing a
value of 0ms to the MFR_WATCHDOG_T register disables
the watchdog timer. A non-zero write to MFR_WATCHDOG_T will reset the watchdog timer.
MFR_WATCHDOG_T_POR and MFR_WATCHDOG_T Data
Contents
BIT(S) SYMBOL
OPERATION
b[15:0] Mfr_watchdog_t_first The data uses the linear format:
Mfr_watchdog_t
T(Symbol) = Y • 2N
Where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
These timers operate on an internal
clock independent of SHARE_CLK.
Delays are rounded to the nearest 10µs
for _t and 1ms for _t_first.
Writing a zero value for Y to the
Mfr_watchdog_t or Mfr_watchdog_t_
first registers will disable the watchdog
timer.
Units: ms. Max timeout is 0.6 sec for _t
and 65 sec for _t_first
This delay is counted using
internal clock independent of
SHARE_CLK.
Delays are rounded to the
nearest 200µs
Units: ms. Max delay is 13.1
sec.
2978fa
43
LTC2978
Operation
MFR_PAGE_FF_MASK
b[5]
The MFR_PAGE_FF_MASK command is used to select
which channels respond when the global page (FF) is in
use. Note that the only commands that support PAGE =
‘hFF are OPERATION and ON_OFF_CONFIG.
b[4]
Mfr_pads_control1
1: Logic high detected on
CONTROL1 pad
0: Logic low detected on
CONTROL1 pad
1: Logic high detected on
CONTROL0 pad
Mfr_pads_control0
0: Logic low detected on
CONTROL0 pad
Bit[3] used for FAULTB00 pad,
bit[2] used for FAULTB01 pad,
bit[1] used for FAULTB10 pad,
bit[0] used for FAULTB11 pad
as follows:
MFR_PAGE_FF_MASK Data Contents
BIT(S) SYMBOL
OPERATION
b[7:0] Mfr_page_ff_mask Global page response enable, per channel
Each bit enables/disables the
corresponding channel:
0 = ignore global page accesses
1 = fully respond to global page accesses
b[3:0]
Mfr_pads_faultb[3:0]
1: Logic high detected on
FAULTBzn pad
0: Logic low detected on
FAULTBzn pad
MFR_PADS
The MFR_PADS command provides read only access to
slow frequency digital pads. The input values presented
in bits[9:0] are before any deglitching logic.
MFR_PADS_PWRGD_DRIVE Data Contents
BIT(S) SYMBOL
b[15] Mfr_pads_pwrgd_drive
b[14]
Mfr_pads_alertb_drive
OPERATION
0 = PWRGD pad is being driven
low by this chip
1 = PWRGD pad is not being
driven low by this chip
0 = ALERTB pad is being driven
low by this chip
1 = ALERTB pad is not being
driven low by this chip
b[13:10] Mfr_pads_faultb_drive[3.0] Bit[3] used for FAULTB00 pad,
bit[2] used for FAULTB01 pad,
bit[1] used for FAULTB10 pad,
bit[0] used for FAULTB11 pad
as follows:
0 = FAULTB pad is being driven
low by this chip
b[9:8]
Mfr_pads_asel1[1:0]
1 = FAULTB pad is not being
driven low by this chip
11: Logic high detected on ASEL1
input pad
10: ASEL1 input pad is floating
01: Reserved
b[7:6]
Mfr_pads_asel0[1:0]
00: Logic low detected on ASEL1
input pad
11: Logic high detected on ASEL0
input pad
10: ASEL0 input pad is floating
MFR_I2C_BASE_ADDRESS
The MFR_I2C_BASE_ADDRESS command determines the
base value for the I2C address byte.
MFR_I2C_BASE_ADDRESS Data Contents
BIT(S) SYMBOL
b[7]
Reserved
b[6:0] i2c_base_address
OPERATION
Read only, always returns 0.
This 7-bit value determines the base value
of the 7-bit I2C address.
MFR_SPECIAL_ID
This register contains the manufacturer ID for the
LTC2978.
MFR_SPECIAL_ID Data Contents
BIT(S)
SYMBOL
OPERATION
b[15:0]
Mfr_special_id
Read only, always returns ‘h0121
MFR_SPECIAL_LOT
These paged registers contain information that identifies the
user configuration that was programmed at the factory.
MFR_SPECIAL_LOT Data Contents
BIT(S)
SYMBOL
OPERATION
b[7:0]
Mfr_special_lot
Contains the LTC default special lot
number. Contact the factory to request
a custom factory programmed user
configuration and special lot number.
01: Reserved
00: Logic low detected on ASEL0
input pad
2978fa
44
LTC2978
Operation
MFR_VOUT_DISCHARGE_THRESHOLD
MFR_FAULT_LOG_CLEAR
This register contains the coefficient that multiplies
VOUT_COMMAND in order to determine the OFF threshold voltage for the associated output. If the output voltage has not decayed below MFR_VOUT_DISCHARGE_
THRESHOLD • VOUT_COMMAND prior to the channel
being commanded to enter/re-enter the ON state, bit [7]
in the STATUS_MFR_SPECIFIC register will be set and the
ALERTB pin will be asserted low. In addition, the channel
will not enter the ON state until the output has decayed
below its OFF threshold voltage.
This command initializes the EEPROM block reserved for
fault logging. Any previous fault log stored in EEPROM
will be erased by this operation.
Other channels can be held off if a particular output has
failed to discharge by using the bidirectional FAULTzn pins
(refer to the MFR_FAULTBzn_RESPONSE and MFR_FAULTBzn_PROPAGATE registers).
MFR_FAULT_LOG_STATUS
Read only. This register is used to manage fault log
events.
Mfr_fault_log_status_eeprom is set after a MFR_FAULT_
LOG_STORE command or a faulted-off event triggers a
transfer of the fault log from RAM to EEPROM. This bit is
cleared by a MFR_FAULT_LOG_CLEAR command.
BIT(S)
SYMBOL
OPERATION
Mfr_fault_log_status_ram is set after a MFR_FAULT_
LOG_RESTORE to indicate that the data in the RAM has
been restored from EEPROM and not yet read using a
MFR_FAULT_LOG command. This bit is cleared by a
MFR_FAULT_LOG command.
b[15:0]
Mfr_vout_discharge_
threshold
The data uses the linear format:
k = Y • 2N
MFR_FAULT_LOG_STATUS Data Contents
MFR_VOUT_DISCHARGE_THRESHOLD Data Contents
Where N=b[15:11] is a 5-bit two’s
complement integer and Y= b[10:0]
is an 11-bit two’s complement
integer.
BIT(S) SYMBOL
b[1]
This command allows the user to transfer data from the
RAM buffer to EEPROM.
MFR_FAULT_LOG_RESTORE
This command allows the user to transfer a copy of the
fault-log data from the EEPROM to the RAM buffer. After
a restore the RAM buffer is locked until a successful
Mfr_fault_log read.
Fault log RAM status:
0: The fault log RAM allows
updates.
Units: Dimensionless, this register
contains a coefficient.
MFR_FAULT_LOG_STORE
Mfr_fault_log_status_ram
OPERATION
1: The fault log RAM is locked
until the next Mfr_fault_log
read.
b[0]
Mfr_fault_log_status_eeprom Fault log EEPROM status:
0: The transfer of the fault log
RAM to the EEPROM is enabled.
1: The transfer of the fault
log RAM to the EEPROM is
inhibited.
2978fa
45
LTC2978
Operation
MFR_FAULT_LOG
Read only. This 2048-bit data block contains a copy of
the RAM buffer fault log. The RAM buffer is continuously
updated after each ADC conversion as long as Mfr_fault_
log_status_ram is clear. With Mfr_config_fault_log_en = 1
and Mfr_fault_log_status_eeprom = 0, the RAM buffer is
transferred to EEPROM whenever an LTC2978 fault causes
a channel to latch off or a MFR_FAULT_LOG_STORE command is received. Mfr_fault_log_status_eeprom is set
high after the RAM buffer is transferred to EEPROM and
not cleared until a Mfr_fault_log_clear is received; even if
the LTC2978 is reset or powered down. Fault log EEPROM
transfers are not initiated as a result of Status_mfr_discharge, Status_mfr_fault1_in or Status_mfr_fault0_in
events. During a Mfr_fault_log read, data is returned one
byte at a time as defined by the following table. The fault
log stores approximately 1 to 2 seconds of telemetry.
MFR_FAULT_LOG Data Block Contents
DATA
BYTE
Position_last[7:0]
0
SharedTime[7:0]
SharedTime[15:8]
SharedTime[23:16]
SharedTime[31:24]
SharedTime[39:32]
SharedTime[40]
Mfr_vout_peak0[7:0]
Mfr_vout_peak0[15:8]
Mfr_vout_min0[7:0]
Mfr_vout_min0[15:8]
Mfr_vout_peak1[7:0]
Mfr_vout_peak1[15:8]
Mfr_vout_min1[7:0]
Mfr_vout_min1[15:8]
Mfr_vin_peak[7:0]
Mfr_vin_peak[15:8]
Mfr_vin_min[7:0]
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
BLOCK READ COMMAND
Position of fault log pointer
when fault occurred.
41-bit share-clock counter
value when fault occurred.
Counter LSB is in 200µs
increments. This counter is
cleared at power-up or after
the LTC2978 is reset
MFR_FAULT_LOG Data Block Contents
DATA
BYTE
Mfr_vin_min[15:8]
18
Mfr_vout_peak2[7:0]
19
Mfr_vout_peak2[15:8]
20
Mfr_vout_min2[7:0]
21
Mfr_vout_min2[15:8]
22
Mfr_vout_peak3[7:0]
23
Mfr_vout_peak3[15:8]
24
Mfr_vout_min3[7:0]
25
Mfr_vout_min3[15:8]
26
Mfr_temp_peak[7:0]
27
Mfr_temp_peak[15:8]
28
Mfr_ temp_min[7:0]
29
Mfr_ temp_min[15:8]
30
Mfr_vout_peak4[7:0]
31
Mfr_vout_peak4[15:8]
32
Mfr_vout_min4[7:0]
33
Mfr_vout_min4[15:8]
34
Mfr_vout_peak5[7:0]
35
Mfr_vout_peak5[15:8]
36
Mfr_vout_min5[7:0]
37
Mfr_vout_min5[15:8]
38
Mfr_vout_peak6[7:0]
39
Mfr_vout_peak6[15:8]
40
Mfr_vout_min6[7:0]
41
Mfr_vout_min6[15:8]
42
Mfr_vout_peak7[7:0]
43
Mfr_vout_peak7[15:8]
44
Mfr_vout_min7[7:0]
45
Mfr_vout_min7[15:8]
46
BLOCK READ COMMAND
47 bytes for preamble
Fault_log [Position_last]
Fault_log [Position_last-1]
.
.
.
Fault_log [Position_last-201]
Reserved
47
48
247
248-255
Number of loops
(248-47)/40 = 5
2978fa
46
LTC2978
Operation
Data is logged into memory in the order shown in the
following table.
POSITION
32
33
34
35
36
37
38
39
When data is returned during a block read it is returned in
reverse order based on the value of Position_last[7:0]. Data
byte Read_vout0[7:0] is followed by Status_mfr of page 7.
Example: If Position_last = 9 then the first data returned in
byte position 47 of a block read is Read_vin[15:8] followed
by Read_vin[7:0] followed by Status_mfr of page 1.
POSITION
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
DATA
Read_vout0[7:0]
Read_vout0[15:8]
Status_vout0
Status_mfr0
Read_vout1[7:0]
Read_vout1[15:8]
Status_vout1
Status_mfr1
Read_vin[7:0]
Read_vin[15:8]
Status_vin
Reserved
Read_vout2[7:0]
Read_vout2[15:8]
Status_vout2
Status_mfr2
Read_vout3[7:0]
Read_vout3[15:8]
Status_vout3
Status_mfr3
Read_temperature_1[7:0]
Read_temperature_1[15:8]
Status_temp
Reserved
Read_vout4[7:0]
Read_vout4[15:8]
Status_vout4
Status_mfr4
Read_vout5[7:0]
Read_vout5[15:8]
Status_vout5
Status_mfr5
DATA
Read_vout6[7:0]
Read_vout6[15:8]
Status_vout6
Status_mfr6
Read_vout7[7:0]
Read_vout7[15:8]
Status_vout7
Status_mfr7
Total Bytes =40
MFR_COMMON
This command returns status information for the shareclock pin (SCLK) and the write-protect pin (WP).
MFR_COMMON Data Contents
BIT(S)
SYMBOL
OPERATION
b[7:2]
Reserved
Read only, always returns 0s
b[1]
Mfr_common_
share_clk
Returns status of share-clock pin
1: Share-clock pin is being held low
0: Share-clock pin is active
b[0]
Mfr_common_
write_protect
Returns status of write-protect pin
1: Write-protect pin is high
0: Write-protect pin is low
MFR_SPARE0
This 16-bit wide registers can be used to store miscellaneous information. The contents of these registers
may be stored and recalled from EEPROM using the
STORE_USER_ALL and RESTORE_USER_ALL commands, respectively.
MFR_SPARE2
These 16-bit wide, paged registers can be used to store
miscellaneous information. The contents of these registers may be stored and recalled from EEPROM using
the STORE_USER_ALL and RESTORE_USER_ALL commands, respectively.
2978fa
47
LTC2978
Operation
MFR_VOUT_MIN
MFR_TEMPERATURE_MIN
This command returns the minimum ADC measured value
of the channel’s output voltage. The contents of this register is reset to ‘hFFFF when the LTC2978 emerges from
power-on reset or when a CLEAR_FAULTS command is
executed. When odd channels are configured to measure
current, this command is not supported.
This command returns the minimum ADC measured
value of junction temperature in °C as determined by the
LTC2978’s internal temperature sensor. The contents of
this register is reset to ‘h7BFF when the LTC2978 emerges
from power-on reset or when a CLEAR_FAULTS command
is executed.
MFR_VOUT_MIN Data Contents
MFR_TEMPERATURE_MIN Data Contents
BIT(S)
SYMBOL
OPERATION
BIT(S)
b[15:0]
Mfr_vout_min
The data uses the linear mode format
as defined by VOUT_MODE:
b[15:0] Mfr_temperature_min The data uses the linear format:
V(mfr_vout_min) = Y • 2N
Where Y = b[15:0] is an unsigned
integer and N = Vout_mode_parameter
is a 5-bit two’s complement exponent
that’s hardwired to a value of –13
decimal.
SYMBOL
OPERATION
V(mfr_vin_min) = Y • 2N
Where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Units: °C.
Units: V.
MFR_VIN_MIN
This command returns the minimum ADC measured value
of the input voltage. The contents of this register is reset
to ‘h7BFF when the LTC2978 emerges from power-on
reset or when a CLEAR_FAULTS command is executed.
Updates are disabled when unit is off for insufficient input
voltage.
MFR_VIN_MIN Data Contents
BIT(S)
SYMBOL
OPERATION
b[15:0]
Mfr_vin_min
The data uses the linear format:
V(mfr_vin_min) = Y • 2N
Where N = b[15:11] is a 5-bit two’s
complement integer and
Y = b[10:0] is an 11-bit two’s
complement integer
Units: V.
2978fa
48
LTC2978
Operation
Watchdog
Other Operations
A non-zero write to the MFR_WATCHDOG_T register will
reset the watchdog timer. Low-to-high transitions on the
WDI pin also reset the watchdog timer. If the timer expires,
ALERTB is asserted and the PWRGD output is optionally
deasserted and then reasserted after MFR_PWRGD_ASSERTION_DELAY ms. Writing 0 to either the MFR_WATCHDOG_T or MFR_WATCHDOG_T_FIRST registers will
disable the timer.
Clock Sharing
Reset
Holding the WDI pin low for more than tRESETB will cause
the LTC2978 to enter the power-on reset state. Following
the subsequent rising-edge of the WDI pin, the LTC2978
will execute its power-on sequence per the user configuration stored in EEPROM.
Multiple LTC2978s can synchronize their clocks in an application by connecting together the open-drain SHARE_CLK
input/outputs to a pull-up resistor as a wired AND. In this
case the fastest clock will take over and synchronize all
LTC2978s.
The LTC2978 can be configured to respond to the
SHARE_CLK pin being held low by disabling all channels
after a brief de-glitch period. When the SHARE_CLK pin
is allowed to rise, the LTC2978 will respond by beginning
a soft-start sequence.
The LTC2978 can be configured to hold SHARE_CLK
low when the unit is off for insufficient input voltage by
writing b[3] = 1 “mfr_config_vin_share_enable” of the
MFR_CONFIG_ALL register.
Write-Protect Pin
The WP pin allows the user to write-protect the LTC2978’s
configuration registers. The WP pin is active high, and
when asserted it overrides the WRITE_PROTECT command register. All registers are write-protected by the
WP pin except for PAGE, OPERATION, CLEAR_FAULTS,
MFR_PAGE_FF_MASK and STORE_USER_ALL.
2978fa
49
LTC2978
Applications Information
LTC2978 Overview
Some examples of typical ON/OFF configurations are:
The LTC2978 is a power management IC that is capable
of sequencing, margining, trimming, OV/UV supervision,
providing fault management, and voltage read back for
eight DC/DC converters. Input voltage and temperature
read back is also available. Odd numbered channels can be
configured to read back sense resistor voltages. Multiple
LTC2978s can be synchronized to operate in unison using
the SHARE_CLK, FAULTB and CONTROL pins. The LTC2978
utilizes a PMBus compliant interface and command set.
1.A DC/DC may be configured to turn on anytime VIN
exceeds VIN_ON.
Setting Command Register Values
The command register settings described herein are for
the purpose of understanding and software development
in a host processor. In actual practice, the LTC2978 can
be completely configured for standalone operation with
the LTC DC590B dongle and software GUI using intuitive
menu driven objects.
Command Units On or Off
Three control parameters determine how a particular
channel is turned on and off. The CONTROLn pins, the
OPERATION command and the value of the input voltage
measured at the VIN_SNS pin (VIN). In all cases, VIN must
exceed VIN_ON in order to enable a start. When VIN drops
below VIN_OFF , an immediate shutdown of all channels
will result. Refer to the OPERATION section in the data
sheet for a detailed description of the ON_OFF_CONFIG
command.
2. A DC/DC may be configured to turn on only when it
receives an OPERATION command.
3. A DC/DC may be configured to turn on only via the
CONTROL pin.
4. A DC/DC may be configured to turn on only when it
receives an OPERATION command and the CONTROL
pin is asserted.
On Sequencing
The TON_DELAY command sets the amount of time that
a channel will wait following the start of an ON sequence
before its VOUT_ENn pin will enable a DC/DC converter. Once
the DC/DC converter has been enabled, the TON_RISE
command determines the amount of time the LTC2978
waits before the VDACPn output is soft-connected and the
DC/DC converter output is servoed to VOUT_COMMAND
volts. The TON_MAX_FAULT_LIMIT command determines
the amount of time after the DC/DC converter has been
enabled that an undervoltage condition will be tolerated
before a fault occurs. If a TON_MAX_FAULT occurs, the
channel can be configured to disable the DC/DC converter
and propagate the fault to other channels using the bidirectional FAULTBzn pins. Figure 11 shows a typical onsequence using the CONTROL pin.
VCONTROL
VOUT_EN
VOUT_0V_FAULT_LIMIT
DAC SOFT-CONNECTS
AND BEGINS
ADJUSTING OUTPUT
VOUT_COMMAND
VDC_NOM
VOUT_UV_FAULT_LIMIT
VOUT
2978 F11
TON_DELAY
TON_RISE
TON_MAX_FAULT_LIMIT
Figure 11. Typical On Sequence Using Control Pin
2978fa
50
LTC2978
APPLICATIONS INFORMATION
ON State Operation
Once a channel has reached the ON state, the OPERATION
command can be used to command the DC/DC converter’s
output to margin high, margin low, or return to a nominal
output voltage indicated by VOUT_COMMAND. The user also
has the option of configuring a channel to continuously trim
the output of the DC/DC converter to the VOUT_COMMAND
voltage, or the channel’s VDACPn output can be placed in a
high impedance state thus allowing the DC/DC converter
output voltage to go to its nominal value, VDCn (NOM). Refer to
the MFR_CONFIG command for details on how to configure
the output voltage servo.
Off Sequencing
An off sequence is initiated using the CONTROLn pin or
the OPERATION command. The TOFF_DELAY command
determines the amount of time that elapses from the beginning of the off sequence until each channel’s VOUT_EN
pin is pulled low thus disabling its DC/DC converter.
VOUT Off Threshold Voltage
The MFR_VOUT_DISCHARGE_THRESHOLD command
register allows the user to specify the OFF threshold that
the output voltage must decay below before the channel can enter/re-enter the ON state. The OFF threshold
voltage is specified by multiplying MFR_VOUT_DISCHARGE_THRESHOLD and VOUT_COMMAND. In the
event that an output voltage has not decayed below its
OFF threshold before attempting to enter the ON state,
the channel will continue to be held off, the appropriate
bit is set in the STATUS_MFR_SPECIFIC register, and the
ALERTB pin will be asserted low. When the output voltage has decayed below its OFF threshold, the channel can
enter the ON state.
Automatic Restart via MFR_RESTART_DELAY
Command
If the CONTROLn pin is toggled quickly (>10µs deglitch),
an automatic restart sequence can be triggered using the
MFR_RESTART_DELAY command for the channels enabled
by the CONTROLn pin (see Figure 12).
VOUT OV/UV Faults
The high speed voltage supervisor OV and UV fault thresholds are configured using the VOUT_OV_FAULT_LIMIT
and VOUT_UV_FAULT_LIMIT commands, respectively.
The VOUT_UV_FAULT_RESPONSE and VOUT_UV_FAULT_
RESPONSE commands determine the response to an
OV/UV fault. Fault responses can range from disabling
the DC/DC converter immediately, waiting to see if the
fault condition persists for some interval before disabling
the DC/DC converter, or allowing the DC/DC converter
to continue operating in spite of the fault. If a DC/DC
converter is disabled, the LTC2978 can be configured to
retry or latch-off. The retry interval is specified using the
MFR_RETRY_DELAY command. Latched faults are reset
by toggling the CONTROLn pin, using the OPERATION
command, or removing and reapplying the bias voltage
(VIN_SNS pin). All fault and warning conditions result in
the ALERTB pin being asserted low and the corresponding
bits being set in the status registers. The CLEAR_FAULTS
command resets the contents of the status registers and
deasserts the ALERTB output.
CONTROL
PIN BOUNCE
VCONTROL
VOUT_END
2978 F012
TOFF_DELAY0
MFR_RESTART_DELAY
TON_DELAY0
Figure 12. Off Sequence with Automatic Restart
2978fa
51
LTC2978
APPLICATIONS INFORMATION
VOUT OV/UV Warnings
Multichannel Fault Management
OV and UV warning threshold voltages are processed
by the LTC2978’s ADC. These thresholds are set by the
VOUT_OV_WARN_LIMIT and VOUT_UV_WARN_LIMIT
commands. If a warning occurs, the corresponding bits
are set in the status registers and the ALERTB output
is asserted low. Note that a warning will never cause a
VOUT_ENn output to disable a DC/DC converter.
Multichannel fault management is handled using the
bidirectional FAULTBzn pins. The “z” designates the fault
zone which is either 0 or 1. There are two fault zones in
the LTC2978. Each zone contains 4-channels. Figure 13
illustrates the connections between channels and the
FAULTBzn pins.
Configuring the VIN_EN Output
The VIN_EN output may be used to disable the intermediate bus voltage in the event of an output OV or UV
fault. Use the MFR_VINEN_OV_FAULT_RESPONSE and
MFR_VINEN_UV_FAULT_RESPONSE registers to configure the VIN_EN pin to assert low in response to VOUT_OV/UV
fault conditions. The VIN_EN output will stop pulling low
when the LTC2978 is commanded to re-enter the ON state
following a faulted-off condition.
A charge-pumped 5µA pull-up to 12V is also available
on the VIN_EN output. Refer to the MFR_CONFIG_ALL
register description in the OPERATION section for more
information.
Figure 23 shows an application circuit where the VIN_EN
output is used to trigger a SCR crowbar on the intermediate
bus in order to protect the DC/DC converter’s load from a
catastrophic fault such as a stuck top gate.
• The MFR_FAULTBz0_PROPAGATE command acts like
a programmable switch that allows faulted-off conditions from a particular channel (PAGE) to propagate
to either FAULTBzn output in that channel’s zone. The
MFR_FAULTBzn_RESPONSE command controls similar
switches on the inputs to each channel that allow any
channel to shut down in response to any combination of
the FAULTBzn pins within a zone. Channels responding
to a FAULTBzn pin pulling low will attempt a new start
sequence when the FAULTBzn pin in question is released
by the faulted channel.
• To establish dependencies across fault zones, tie the
fault pins together, e.g., FAULTB01 to FAULTB10. Any
channel can depend on any other. To disable all channels in response to any channel faulting off, short all
the FAULTBzn pins together, and set MFR_FAULTBzn_
PROPAGATE = ‘h01 and MFR_FAULTBzn_RESPONSE
= ‘h0F for all channels.
• A FAULTBzn pin can also be asserted low by an external
driver in order to initiate an immediate off-sequence
after a 10µs deglitch delay.
2978fa
52
LTC2978
APPLICATIONS INFORMATION
MFR_FAULTB00_RESPONSE, PAGE = 0
MFR_FAULTB01_RESPONSE, PAGE = 0
MFR_FAULTB00_PROPAGATE, PAGE = 0
CHANNEL 0
EVENT PROCESSOR
PAGE = 0
MFR_FAULTB00_RESPONSE, PAGE = 1
MFR_FAULTB01_RESPONSE, PAGE = 1
CHANNEL 1
EVENT PROCESSOR
PAGE = 1
MFR_FAULTB01_PROPAGATE, PAGE = 1
MFR_FAULTB00_PROPAGATE, PAGE = 2
CHANNEL 2
EVENT PROCESSOR
PAGE = 2
MFR_FAULTB00_RESPONSE, PAGE = 3
MFR_FAULTB01_RESPONSE, PAGE = 3
FAULTB00
MFR_FAULTB00_PROPAGATE, PAGE = 1
MFR_FAULTB00_RESPONSE, PAGE = 2
MFR_FAULTB01_RESPONSE, PAGE = 2
MFR_FAULTB01_PROPAGATE, PAGE = 0
FAULTB01
MFR_FAULTB01_PROPAGATE, PAGE = 2
MFR_FAULTB00_PROPAGATE, PAGE = 3
CHANNEL 3
EVENT PROCESSOR
PAGE = 3
MFR_FAULTB01_PROPAGATE, PAGE = 3
ZONE 0
ZONE 0
ZONE 1
ZONE 1
MFR_FAULTB10_RESPONSE, PAGE = 4
MFR_FAULTB11_RESPONSE, PAGE = 4
MFR_FAULTB10_PROPAGATE, PAGE = 4
CHANNEL 4
EVENT PROCESSOR
PAGE = 4
MFR_FAULTB10_RESPONSE, PAGE = 5
MFR_FAULTB11_RESPONSE, PAGE = 5
CHANNEL 5
EVENT PROCESSOR
PAGE = 5
MFR_FAULTB11_PROPAGATE, PAGE = 5
MFR_FAULTB10_PROPAGATE, PAGE = 6
CHANNEL 6
EVENT PROCESSOR
PAGE = 6
MFR_FAULTB10_RESPONSE, PAGE = 7
MFR_FAULTB11_RESPONSE, PAGE = 7
FAULTB10
MFR_FAULTB10_PROPAGATE, PAGE = 5
MFR_FAULTB10_RESPONSE, PAGE = 6
MFR_FAULTB11_RESPONSE, PAGE = 6
MFR_FAULTB11_PROPAGATE, PAGE = 4
FAULTB11
MFR_FAULTB11_PROPAGATE, PAGE = 6
MFR_FAULTB10_PROPAGATE, PAGE = 7
CHANNEL 7
EVENT PROCESSOR
PAGE = 7
MFR_FAULTB11_PROPAGATE, PAGE = 7
2978 F13
Figure 13. Channel Fault Management Block Diagram
2978fa
53
LTC2978
APPLICATIONS INFORMATION
Interconnect Between Multiple LTC2978s
Figure 14 shows how to interconnect the pins in a typical
multi-LTC2978 array.
• All VIN_SNS lines should be tied together in a star type
connection at the point where VIN is to be sensed.
This will minimize timing errors for the case where the
ON_OFF_CONFIG is configured to start the LTC2978
based on VIN and ignore the CONTROLn line and the
OPERATION command. In multi-part applications that
are sensitive to timing errors, it is recommended that
the Vin_share_enable bit of the MFR_CONFIG_ALL
register be set high in order to allow SHARE_CLK to
synchronize on/off sequencing in response to the VIN_ON
and VIN_OFF thresholds.
• Connecting all VIN_EN lines together will allow an
overvoltage (OV) fault on any DC/DC converter’s output
in the array to shut off a common input switch.
• ALERTB is typically one line in an array of PMBus
converters. The LTC2978 allows a rich combination of
faults and warnings to be propagated to the ALERTB
pin.
• WDI/RESET can be used to put the LTC2978 in the
power-on reset state. Pull WDI/RESET low for at least
tRESETB to enter this state.
• The FAULTBzn lines can be connected together to create
fault dependencies. Figure 14 shows a configuration
where a fault on any FAULTBzn will pull all others low.
This is useful for arrays where it is desired to abort a
startup sequence in the event any channel does not
come up (see Figure 15).
• PWRGD reflects the status of the outputs that are
mapped to it by the MFR_PWRGD_EN command. Figure 14 shows all the PWRGD pins connected together,
but any combination may be used.
TO VIN OF
DC/DCs TO HOST CONTROLLER
LTC2978 1
VIN_SNS
VIN_EN
SDA
SCL
ALERTB
CONTROL0
CONTROL1
WDI/RESET
FAULTB00
FAULTB01
FAULTB10
FAULTB11
SHARE_CLK
PWRGD
GND
TO INPUT
SWITCH
LTC2978 #n
VIN_SNS
VIN_EN
SDA
SCL
ALERTB
CONTROL0
CONTROL1
WDI/RESET
FAULTB00
FAULTB01
FAULTB10
FAULTB11
SHARE_CLK
PWRGD
GND
TO OTHER LTC2978s–10k EQUIV PULL-UP RECOMMENDED
ON EACH LINE EXCEPT SHARE_CLK (USE 5.49k)
2978 F14
Figure 14. Typical Connections Between Multiple LTC2978s
2978fa
54
LTC2978
APPLICATIONS INFORMATION
Trimming and Margining DC/DC Converters with
External Feedback Resistors
is developed between the VDACP0 and VDACM0 pins by the
closed-loop servo algorithm. VDACM0 is Kelvin connected
to the point-of-load GND in order to minimize the effects
of load induced grounding errors. The VDACP0 output is
connected to the DC/DC converter’s feedback node through
resistor R30.
Figure 16 shows a typical application circuit for trimming/margining a power supply with an external feedback
network. The VSENSEP0 and VSENSEM0 differential inputs
sense the load voltage directly, and a correction voltage
VCONTROLn
VOUT0
TON_DELAY0
VOUT1
TON_DELAY1
VOUT2
TON_DELAY2
•
•
•
VOUTn
•
•
•
TON_DELAYn
BUSSED
VFAULTBzn
PINS
2978 F15
TON_MAX_FAULT1
Figure 15. Aborted On Sequence Due to Channel 1 Short
VIN
4.5V < VIBUS < 15V
0.1µF
VIN
VPWR
VIN_SNS
VOUT
VDACP0
VDD33
VDD33
VDD25
R30
VSENSEP0
LTC2978*
DC/DC
CONVERTER
VFB
LOAD
VDACM0
0.1µF
R20
R10
VSENSEM0
SGND
VOUT_EN0
RUN/SS
GND
2978 F16
GND
*SOME DETAILS OMITTED FOR CLARITY
ONLY ONE OF EIGHT CHANNELS SHOWN
Figure 16. Application Circuit for DC/DC Converters with External Feedback Resistors
2978fa
55
LTC2978
APPLICATIONS INFORMATION
4-Step Resistor Selection Procedure for DC/DC
Converters with External Feedback Resistors
The following 4-step procedure should be used to calculate the resistor values required for the application circuit
shown in Figure 16.
1. Assume values for feedback resistor R20 and the nominal
DC/DC converter output voltage VDC0(NOM), and solve
for R10.
VDC0(NOM) is the output voltage of the DC/DC converter
when the LTC2978’s VDACP0 pin is in a high impedance
state. R10 is a function of R20, VDC0(NOM), the voltage at
the feedback node (VFB) when the loop is in regulation,
and the feedback node’s input current (IFB).
R20 • VFB0
R10 =
VDC(NOM) – IFB0 • R20 – VFB
(1)
2. Solve for the value of R30 that yields the maximum
required DC/DC converter output voltage VDC0(MAX).
When VDACP0 is at 0V, the output of the DC/DC converter
is at its maximum voltage.
R30 ≤
R20 • VFB
VDC(MAX ) – VDC(NOM) (2)
3. Solve for the minimum value of VDACP0 that’s needed
to yield the minimum required DC/DC converter output
voltage VDC0(MIN).
The voltage-buffered current DAC has two full-scale
settings, 1.33V ±3.7% and 2.7V ±3.7%. In order to
select the appropriate full-scale setting, calculate the
maximum required VDAC0P output voltage:
(
)
VDACP0 > VDC(NOM) – VDC(MIN) •
R30
+ VFB
R20
(3)
4. Recalculate the minimum, nominal, and maximum
DC/DC converter output voltages and the resulting
margining resolution.
VDC(NOM) = VFB • 1 +
R20
+ IFB • R20
R10
(
(4)
)
R20
• VDACP0(F / S) – VFB (5)
R30
R20
VDC0(MAX ) = VDC(NOM) +
•V
(6)
R30 FB
R20
• VDACP0(F / S)
VRES = R30
V/DAC LSB
(7)
1024
VDC0(MIN) = VDC0(NOM) –
2978fa
56
LTC2978
APPLICATIONS INFORMATION
Trimming and Margining DC/DC Converters
with a TRIM Pin
Figure 17 illustrates a typical application circuit for trimming/margining the output voltage of a DC/DC converter
with a TRIM Pin. The LTC2978’s VDACPn pin connects to
the TRIM pin through resistor R30, and the VDACM0 pin is
connected to the converter’s point-of-load ground.
DC/DC converters with a TRIM pin are typically margined
high or low by connecting an external resistor between
the TRIM pin and either the VSENSEP or VSENSEM pin. The
relationships between these resistors and the ∆% change
in the output voltage of the DC/DC converter are typically
expressed as:
RTRIM _ DOWN =
RTRIM • 50
– RTRIM
∆DOWN %
)
The following 2-step procedure should be used to calculate
the resistor value for R30 and the required full-scale DAC
voltage (refer to Figure 17).
1. Solve for R30:
 50 – ∆DOWN % 
R30 ≤ RTRIM • 
 ∆DOWN % 

∆ % 
VDACP0 ≥  1+ UP
•V
∆DOWN %  REF

RTRIM _ UP =
(
2-Step Resistor and DAC Full-Scale Voltage Selection
Procedure for DC/DC Converters with a TRIM Pin
(10)
2. Calculate the maximum required output voltage for
VDACP0:
(8)
 V • 100 + ∆UP %  50  
RTRIM •  DC
–
– 1
 ∆UP %  
 2 • VREF • ∆UP %
∆UP% and ∆DOWN% denote the percentage change in the
converter’s output voltage when margining up or down,
respectively.
(9)
(11)
where RTRIM is the resistance looking into the TRIM pin,
VREF is the TRIM pin’s open-circuit output voltage and
VDC is the DC/DC converter’s nominal output voltage.
VIN
4.5V < VIBUS < 15V
0.1µF
VIN
VPWR
VIN_SNS
VDD33
VSENSEP0
R30
VDACP0
VDD33
VDD25
LTC2978*
GND
TRIM
VSENSE+
LOAD
VDACM0
0.1µF
VOUT+
DC/DC
CONVERTER
VSENSEM0
VSENSE–
VOUT_EN0
ON/OFFB
GND
2978 F17
*SOME DETAILS OMITTED FOR CLARITY
ONLY ONE OF EIGHT CHANNELS SHOWN
Figure 17. Application Circuit for DC/DC Converters with Trim Pin
2978fa
57
LTC2978
APPLICATIONS INFORMATION
Measuring Current
differential mode noise from the inductor of the switching
DC/DC converter. The filter to the ADC is placed directly
across the inductor or a sense resistor in series with the
inductor. Note that the + input to the ADC must be limited
to <6V above ground. Select RCM and CCM such that the
corner frequency is ≤1/10 the DC/DC converter switching
frequency and ≤1/10 of the internal 62.5kHz clock of the
LTC2978’s ∆Σ ADC. This will assure that the DC value
at the (+) input to the ADC will be equal to the output
voltage with small ripple. Good values are RCM = 100Ω,
CCM ≥ 1µF. Keep RCM ≤ 100Ω to minimize gain errors due
to ADC input resistance.
Odd numbered ADC channels may be used to measure
supply current. Set the ADC to high resolution mode to
configure for current measuring and improve sensitivity.
Note that no OV or UV faults or warnings are reported in
this mode, but telemetry is available from the READ_VOUT
command using the 11-bit signed mantissa plus 5-bit
signed exponent linear data format. Set the MFR_CONFIG
bit b[9] = 1 in order to enable high res mode. Note: Any
channel configured for ADC high res mode should be permanently commanded off, i.e., OPERATION register = ‘h00
(this is the factory default EEPROM value). The VOUT_ENn
will assert low in this mode and cannot be used to control
a DC/DC. The VDACPn output is also unavailable.
Many switching regulator control ICs derive AC inductor
current information from an RC network such as the one
formed by R1, C1, R2 and C2. The proper placement of
the balanced common mode filter for the ADC input is
also shown in Figure 18.
A circuit for measuring current is shown in Figure 18.
The balanced filter, RCM, CCM, rejects common mode and
RCM
LTC2978
CCM
RCM
L
+
CCM
+
–
ADC
DCR
–
LOAD CURRENT
C1
R1
TO
CONTROLLER
IC
+
–
R2
C2
2978 F18
Figure 18. DCR Current Sensing Circuits
2978fa
58
LTC2978
APPLICATIONS INFORMATION
Antialiasing Filter Considerations
Extremely noisy environments may require an antialiasing
filter on the input to the LTC2978’s ADC. The R-C circuit
shown in Figure 19 is adequate for most situations. Keep
R40 = R50 ≤ 200Ω to minimize ADC gain errors, and select
a value for capacitors C10 and C20 that doesn’t add too
much additional response time to the OV/UV supervisor,
e.g. τ ≅ 10µs (R = 100Ω, C = 0.10µF).
VIN
4.5V < VIBUS < 15V
0.1µF
VIN
VPWR
VIN_SNS
VOUT
VDACP0
VDD33
VDD33
VDD25
VSENSEP0
LTC2978*
VSENSEM0
0.1µF
C10
R40
C20
R50
R30
R20
VFB
LOAD
R10
VDACM0
SGND
VOUT_EN0
GND
DC/DC
CONVERTER
*SOME DETAILS OMITTED FOR CLARITY
ONLY ONE OF EIGHT CHANNELS SHOWN
RUN/SS
GND
2978 F09
Figure 19. Antialiasing Filter on VSENSE Lines
2978fa
59
LTC2978
APPLICATIONS INFORMATION
Dongle Connections
Figure 20 illustrates the application schematic for powering
and programming one or more LTC2978’s from the LTC
PMBus controller in the absence of system power. Because
of the controller’s limited current sourcing capability, only
TP0101K-SSOT23
SYSTEM
3.3V
the LTC2978’s and the I2C pull-up resistors should be powered from the ORed 3.3V supply. In addition, any device
sharing I2C bus connections with the LTC2978 should not
have body diodes between the SDA/SCL pins and its VDD
node because this will interfere with bus communication
in the absence of system power.
IDEAL
DIODE
OR’d 3.3V
0.1µF
LTC4412
VIN SENSE
0.1µF
VPWR
VDD33
VDD33
VDD25
GND GATE
CTL
LTC2978
STAT
PIN CONNECTIONS
OMITTED FOR
CLARITY
ISOLATED 3.3V
LTC
CONTROLLER
HEADER
SDA
SDA
SCL
SCL
SHARE_CLK
TO/FROM OTHER
LTC2978s
WP
GND
2978 F10
NOTE: LTC CONTROLLER I2C CONNECTONS ARE OPTO-ISOLATED
ISOLATED 3.3V FROM CONTROLLER CAN BE BACK DRIVEN AND WILL ONLY DRAW < 10µA
ISOLATED 3.3V CURRENT LIMIT = 100mA
Figure 20. LTC Controller Connections for Powering and Communicating with the LTC2978
2978fa
60
LTC2978
APPLICATIONS INFORMATION
PCB Assembly and Layout Suggestions
Bypass Capacitor Placement
The LTC2978 requires 0.1µF bypass capacitors between
the VDD33 pins and GND, the VDD25 pin and GND, and the
REFP pin and REFM pin. If the chip is being powered from
the VPWR input, then that pin should also be bypassed
to GND by a 0.1µF capacitor. In order to be effective,
these capacitors should be made of high quality ceramic
dielectric such as X5R or X7R and be placed as close to
the chip as possible.
Exposed Pad Stencil Design
The LTC2978’s package is thermally and electrically
efficient. This is enabled by the exposed die attach pad
on the under side of the package which must be soldered
down to the PCB or mother board substrate. It is a good
practice to minimize the presence of voids within the
exposed pad inter-connection. Total elimination of voids
is difficult, but the design of the exposed pad stencil is
key. Figure 21 shows a suggested screen print pattern.
The proposed stencil design enables out-gassing of the
solder paste during reflow as well as regulating the finished
solder thickness.
PC Board Layout
Mechanical stress on a PC board and soldering-induced
stress can cause the LTC2978’s reference voltage and
voltage drift to shift. A simple way to reduce these stressrelated shifts is to mount the IC near the short edge of the
PC board, or in a corner. The board edge acts as a stress
boundary, or a region where the flexure of the board is
minimal.
2978 F11
Figure 21. Suggested Screen Pattern for Die Attach Pad
2978fa
61
LTC2978
Typical Application
0.1µF
42
6
VIN
VOUT
45
47
R32
R22
DC/DC
CONVERTER
VFB
LOAD
R12
RUN/SS SGND
GND
48
46
7
51
49
50
52
IN
8
VIN_SNS
ASEL0
ASEL1
VPWR
VDD33
VDD25
WP
GND
REFP
REFM
VDACP7
VSENSEP7
VSENSEM0
VSENSEM7
VDACM0
VDACM7
VOUT_EN0
VOUT_EN7
VDACP1
VDACP6
VSENSEP1
VSENSEP6
VSENSEM1
VSENSEM6
VDACM1
VDACM6
VOUT_EN1
VOUT_EN6
LTC2978
VDACP2
VDACP5
VSENSEP2
VSENSEP5
VSENSEM2
VSENSEM5
VDACM2
VDACM5
VOUT_EN2
VOUT_EN5
VDACP3
VDACP4
VSENSEP3
VSENSEP4
VSENSEM3
VSENSEM4
VDACM3
OUT
INTERMEDIATE
BUS
CONVERTER
15
VOUT_EN3
13
EN
3.3V
24
25
26
27
22
28
29
30
31
32
21
VDACM4
WDI/RESETB
44
33
PWRGD
43
34
CONTROL1
41
16
CONTROL0
5
17
ALERTB
RUN/SS SGND
GND
18
SCL
39
19
SDA
38
20
SHARE_CLK
LOAD
R10
VSENSEP0
65
FAULTB11
VFB
VDACP0
FAULTB10
37
36? 35
FAULTB01
40
R30
R20
FAULTB00
VOUT
DC/DC
CONVERTER
VIN_EN
VIN
NC
14
3.3V
0.1µF
VDD33
0.1µF
VOUT_EN4
VOUT
61
3
4
R37
R27
VIN
DC/DC
CONVERTER
VFB
LOAD
R17
62
SGND RUN/SS
GND
12
VOUT
60
1
2
R36
R26
VIN
DC/DC
CONVERTER
VFB
LOAD
R16
59
SGND RUN/SS
GND
11
VOUT
57
63
64
R35
R25
VIN
DC/DC
CONVERTER
VFB
LOAD
R15
58
SGND RUN/SS
GND
10
VOUT
56
53
54
55
R34
R24
VIN
DC/DC
CONVERTER
VFB
LOAD
R14
SGND RUN/SS
GND
9
2978 F12
23
10k
10k
5.49k
10k
3.3V
TO/FROM OTHER LTC2978s AND MICROCONTROLLER
Figure 22. LTC2978 Application Circuit with 3.3V Chip Power
2978fa
62
LTC2978
Package Description
UP Package
64-Lead Plastic QFN (9mm × 9mm)
(Reference LTC DWG # 05-08-1705 Rev C)
0.70 p0.05
7.15 p0.05
7.50 REF
8.10 p0.05 9.50 p0.05
(4 SIDES)
7.15 p0.05
PACKAGE OUTLINE
0.25 p0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
9 .00 p 0.10
(4 SIDES)
0.75 p 0.05
R = 0.10
TYP
R = 0.115
TYP
63 64
0.40 p 0.10
PIN 1 TOP MARK
(SEE NOTE 5)
1
2
PIN 1
CHAMFER
C = 0.35
7.50 REF
(4-SIDES)
7.15 p 0.10
7.15 p 0.10
(UP64) QFN 0406 REV C
0.200 REF
0.00 – 0.05
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION WNJR-5
2. ALL DIMENSIONS ARE IN MILLIMETERS
3. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE, IF PRESENT
4. EXPOSED PAD SHALL BE SOLDER PLATED
5. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE
6. DRAWING NOT TO SCALE
0.25 p 0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
2978fa
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.
63
LTC2978
Typical Application
RSENSE
0.007Ω
VIN
<15V
Q1
Si4894BDY
VIN
CBYPASS
VIN_SNS
VPWR
VCC
GATE
LTC4210-3
24.3k
10k
SENSE
ON
TIMER GND
100Ω
VOUT
VDACP0
DC/DC
CONVERTER
VSENSEP0
0.1µF
LTC2978*
68Ω
VFB
LOAD
VDACM0
0.01µF
0.22µF
VSENSEM0
SGND
VOUT_EN0
RUN/SS
GND
10k
0.01µF
2907
4.99k
2978 F23
MCR12DC
220Ω
0.1µF
BAT54
REFP
VIN_EN
REFM
VDD33 VDD33 VDD25
GND
0.1µF
*SOME DETAILS OMITTED FOR CLARITY
ONLY ONE OF EIGHT CHANNELS SHOWN
0.1µF
Figure 23. LTC2978 Application Circuit with Crowbar Protection on Intermediate Bus
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
LTC2970
Dual I2C Power Supply Monitor and Margining Controller
14-Bit ∆Σ ADC with < ±0.5% TUE, Dual 8-Bit IDACs with 1x Voltage
Buffers
LTC4151
High Voltage I2C Current and Voltage Monitor
7V to 80V, 12-Bit Resolution
LTC4210-3
Hot Swap™ Controller in 6-Lead SOT-23 Package
Adjustable Analog Current Limit with Circuit Breaker, Fast Response
Limits Peak Fault Current
LTC4412
Low Loss PowerPath™ Controller in ThinSOT™
Replaces Power Supply ORing Diodes, Minimal External Components,
Automatic Switching Between DC Sources, Simplifies Load Sharing with
Multiple Batteries, Low Quiescent Current: 11µA
LTM®4601
8A, Low VIN DC/DC µModule® with PLL, Output Tracking
and Margining
Complete Switch Mode Power Supply, 4.5V to 20V Input Voltage, 0.6V
to 5V Output Voltage, PLL Frequency Synchronization, ±1.5% Regulation
LTM4608
8A, Low VIN DC/DC µModule with Tracking, Margining,
Multiphase and Frequency Synchronization
Complete Switch Mode Power Supply, 2.7V to 5.5V Input Voltage, 0.6V
to 5V Output Voltage, Onboard Frequency Synchronization, ±1.5%
Regulation
µModule is a registered trademark of Linear Technology Corporation. PowerPath, ThinSOT and Hot Swap are trademarks of Linear Technology Corporation.
2978fa
64 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
LT 0909 REV A • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2009