LINER LTC2970CUFD

LTC2970/LTC2970-1
Dual I2C Power
Supply Monitor and
Margining Controller
DESCRIPTIO
U
FEATURES
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The LTC®2970 is a dual power supply monitor and
margining controller with an SMBus compatible I2C bus
interface. A low-drift, on-chip reference and 14-bit ΔΣ A/D
converter allow precise measurements of supply voltages,
load currents or internal die temperature. Fault management allows ⎯A⎯L⎯E⎯R⎯T to be asserted for configurable over
and under voltage fault conditions. Two voltage buffered,
8-bit IDACs allow highly accurate programming of DC/DC
converter output voltages. The IDACs can be configured
to automatically servo the power supplies to the desired
voltages using the ADC. The LTC2970-1 adds a tracking
feature that can be used to turn multiple power supplies
on or off in a controlled manner.
Less Than ±0.5% Total Unadjusted Error 14-Bit ΔΣ
ADC with On-Chip Reference
Dual, 8-Bit IDACs with 1x Voltage Buffers
Linear, Voltage Servo Adjusts Supply Voltages by
Ramping IDAC Outputs Up/Down
I2C™ Bus Interface (SMBus Compatible)
Extensive, User Configurable Fault Monitoring
On-Chip Temperature Sensor
Available in 24-Lead 4mm × 5mm QFN Package
U
APPLICATIO S
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Dual Power Supply Voltage Servo
Monitoring Supply Voltage and Current
Programmable Power Supplies
Programmable Reference
The bus address is set to 1 of 9 possible combinations by
pin strapping the ASEL0 and ASEL1 pins. The LTC2970/
LTC2970-1 are packaged in the 24-lead, 4mm × 5mm
QFN package.
, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
U
TYPICAL APPLICATIO
Dual Power Supply Monitor and Controller (One of Two Channels Shown)
ADC Total Unadjusted Error
vs Temperature
8V TO 15V
0.50 15 PARTS MOUNTED ON PCB
0.1μF
12VIN
IN
VDD
OUT
0.25
1/2 LTC2970
0.1μF
ERROR (%)
VIN
GPIO_CFG
I+
VIN0_BM
I–
VIN0_BP
DC/DC
CONVERTER
RUN/SS
GND
FB
SGND
LOAD
ALERT
VOUT0
SCL
VIN0_AP
SDA
IOUT0
VIN0_AM
I2C BUS
SMBUS
COMPATIBLE
(
GPIO_0
)
0
–0.25
–0.50
–50
REF
ADC VIN = 5V
–25
0
50
25
TEMPERATURE (°C)
75
100
29701 TA01b
GND ASEL0 ASEL1
0.1μF
29701 TA01
29701fc
1
LTC2970/LTC2970-1
U
W W
W
ABSOLUTE
AXI U RATI GS
PIN CONFIGURATION
(Notes 1 and 2)
GPIO_CFG
ASEL1
ASEL0
REF
RGND
TOP VIEW
24 23 22 21 20
VIN0_AP 1
19 SDA
VIN0_AM 2
18 SCL
VIN0_BP 3
17 ALERT
25
VIN0_BM 4
16 GPIO_0
VIN1_AP 5
15 GPIO_1
VIN1_AM 6
14 IOUT0
13 IOUT1
VOUT1
VOUT0
9 10 11 12
12VIN
8
VDD
VIN1_BP 7
VIN1_BM
Supply Voltages:
VDD ......................................................... –0.3V to 6V
12VIN .................................................... –0.3V to 15V
Digital Input/Output Voltages:
ASEL0, ASEL1 ............................ –0.3V to VDD + 0.3V
SDA, SCL, GPIO_CFG,
⎯A⎯L⎯E⎯R⎯T, GPIO_0, GPIO_1.......................... –0.3V to 6V
Analog Voltages:
VIN0_AP, VIN0_AM, VIN0_BP,
VIN0_BM, VIN1_AP, VIN1_AM,
VIN1_BP, VIN1_BM, VOUT0, VOUT1 .............. –0.3V to 6V
IOUT0, IOUT1, REF......................... –0.3V to VDD + 0.3V
RGND.................................................... –0.3V to 0.3V
Operating Temperature Range:
LTC2970C ................................................ 0°C to 70°C
LTC2970I ............................................. –40°C to 85°C
Storage Temperature Range...................– 65°C to 125°C
Lead Temperature (Soldering, 10 sec) .................. 300°C
UFD PACKAGE
24-LEAD (4mm × 5mm) PLASTIC QFN
TJMAX = 125°C, θJA = 37°C/W
EXPOSED PAD (PIN 25) IS GND MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2970CUFD#PBF
LTC2970CUFD#TRPBF
2970
24-Lead (4mm × 5mm) Plastic DFN
0°C to 70°C
LTC2970CUFD-1#PBF
LTC2970CUFD-1#TRPBF
29701
24-Lead (4mm × 5mm) Plastic DFN
0°C to 70°C
LTC2970IUFD#PBF
LTC2970IUFD#TRPBF
2970
24-Lead (4mm × 5mm) Plastic DFN
–40°C to 85°C
LTC2970IUFD-1#PBF
LTC2970IUFD-1#TRPBF
29701
24-Lead (4mm × 5mm) Plastic DFN
–40°C to 85°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
29701fc
2
LTC2970/LTC2970-1
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V12VIN = 12V, VDD and REF pins floating unless otherwise indicated,
CVDD = 100nF and CREF = 100nF.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
4.24
7.5
mA
3.7
5
mA
4.14
4.4
Power-Supply Characteristics
IV12
12VIN Supply Current
V12VIN = 12V, VDD Floating
●
IDD
VDD Supply Current
VDD = 5V, V12VIN = VDD
●
VLKO
VDD Undervoltage Lockout
VDD Ramping-Down, V12VIN = VDD
●
3.7
VDD Undervoltage Lockout Hysteresis
VDD
118
Supply Input Operating Range
Regulator Output Voltage
8V ≤ V12VIN ≤ 15V, –1mA ≤ IVDD ≤ 0
●
4.5
●
4.75
Regulator Output Voltage
Temperature Coefficient
V12VIN
4.95
V
mV
5.75
V
5.25
V
10
ppm/°C
Regulator Output Voltage Load
Regulation
–1mA ≤ IVDD ≤ 0
160
ppm/mA
Regulator Line Regulation
8V ≤ V12VIN ≤ 15V, IVDD = 0mA
80
ppm/V
Regulator Output Short-Circuit Current V12VIN = 12V, VDD = 0V
●
–5
12VIN Supply Operating Range
●
8
–34
–63
mA
15
V
Voltage Reference Characteristics
VREF
Reference Output Voltage
1.229
Reference Voltage Temperature
Coefficient
V
2
●
Reference Overdrive Voltage Input
Range
1
ppm/°C
1.5
V
ADC Characteristics
N_ADC
Resolution
N_ADC = 8.192V/16384
500
TUE_ADC
Total Unadjusted Error
VIN = 3V, VIN = VINn_xP – VINn_xM (Note 3)
●
INL_ADC
Integral Nonlinearity
(Note 4)
●
DNL_ADC
Differential Nonlinearity
(Note 7)
●
VIN_ADC
Input Voltage Range
●
0
VOS_ADC
Offset Error
●
–1000
–4.5
Offset Error Drift
GAIN_ADC
Gain Error
2
–316
μV/LSB
±0.5
%
4.5
LSB
±0.5
LSB
6
V
1000
μV
0.19
Full-Scale VIN = 6V
●
μV/°C
±0.4
%
Gain Error Drift
3
TCONV_ADC
Conversion Time
33.3
ms
CIN_ADC
Input Sampling Capacitance
3
pF
FIN_ADC
Input Sampling Frequency
61.4
kHz
ILEAK_ADC
Input Leakage Current
0V < VIN < 6V
●
ppm/°C
±0.1
μA
IDAC Output Current Characteristics
N_IOUT
Resolution (Guaranteed Monotonic)
INL_IOUT
Integral Nonlinearity
VIOUTn < VDD – 1.5V
●
8
±1
LSB
DNL_IOUT
Differential Nonlinearity
VIOUTn < VDD – 1.5V
●
±1
LSB
IFS-IOUT
Full-Scale Output Current
VIOUTn < VDD – 1.5V, DAC Code = 'hff
●
–276
μA
IDRIFT-IOUT
Output Current Drift
DAC Code = 'hff
IOS-IOUT
Offset Current
DAC Code = 'h00
–236
Bits
–255
32
●
ppm/°C
±0.1
μA
29701fc
3
LTC2970/LTC2970-1
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. V12VIN = 12V, VDD and REF pins floating unless otherwise indicated,
CVDD = 100nF and CREF = 100nF.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Voltage Buffered IDAC Output Characteristics
INL_VOUT
Integral Nonlinearity
RIOUTn = 10kΩ, No Load on VOUTn (Note 5)
●
±1
LSB
DNL_VOUT
Differential Nonlinearity
RIOUTn = 10kΩ, No Load on VOUTn (Note 5)
●
±1
LSB
VOS-VOUT
Offset Voltage
VOS = VOUTn – VIOUTn, No Load on VOUTn
●
Output Voltage Drift
No Load on VOUTn
VOUT
Load Regulation
1.6
±10
0.17
mV
μV/°C
0.1V < VOUTn < VDD – 1.5V, IVOUTn Source = 1mA
–57
ppm/mA
0.1V < VOUTn < VDD – 1.5V, IVOUTn Sink = 1mA
100
ppm/mA
VOUTn High-Z, 0V ≤ VOUTn ≤ VDD
●
Short-Circuit Current Low
VOUTn Shorted to GND
●
–50
mA
Short-Circuit Current High
VOUTn Shorted to VDD
●
50
mA
Leakage Current
1
±100
nA
Soft Connect Comparator Characteristics (CMP0, CMP1)
VOS
Offset Voltage
±3
mV
Temperature Sensor Characteristics
TMP
Gain
0.25
°C/LSB
12VIN Voltage Divider Characteristics
GAIN_12VIN
●
Gain
0.329
0.333
0.335
V/V
Digital Inputs SCL, SDA, GPIO_CFG, GPIO_0, GPIO_1
VIH
VIL
Input High Threshold Voltage
Input Low Threshold Voltage
VHYST
Input Hysteresis
ILEAK
Input Leakage Current
CIN
Input Capacitance
SDA, SCL
●
2.1
V
GPIO_CFG, GPIO_0, GIPO_1
●
1.6
V
SDA, SCL
●
1.5
GPIO_CFG, GPIO_0, GIPO_1
●
1.0
V
V
0.08
0V ≤ VIN ≤ 6V
●
V
±1
10
μA
pF
Three State Inputs ASEL[1:0]
VIH_ASEL
Input High Threshold Voltage
●
VIL_ASEL
Input Low Threshold Voltage
●
IIN,HL
High, Low Input Current
IIN,Z
High Z Input Current
ASEL[1:0] = 0, VDD
VDD – 0.5
0.5
●
●
V
V
±20
±2
μA
μA
Open Drain Outputs SDA, GPIO_CFG, GPIO_0, GPIO_1, ⎯A⎯L⎯E⎯R⎯T
VOL
Output Low Voltage
ISINK = 3mA
●
0.4
V
IOH
Input Leakage Current
0V ≤ VIN ≤ 6V
●
±1
μA
29701fc
4
LTC2970/LTC2970-1
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
400
kHz
I2C Interface Timing Characteristics
fSCL
Serial Clock Frequency
(Note 6)
●
10
tLOW
Serial Clock Low Period
(Note 6)
●
1.3
μs
tHIGH
Serial Clock High Period
(Note 6)
●
0.6
μs
tBUF
Bus Free Time Between Stop and Start
(Note 6)
●
1.3
μs
tHD,STA
Start Condition Hold Time
(Note 6)
●
600
ns
tSU,STA
Start Condition Setup Time
(Note 6)
●
600
ns
tSU,STO
Stop Condition Setup Time
(Note 6)
●
600
ns
tHD,DAT
Data Hold Time (LTC2970 Receiving Data)
(Note 6)
Data Hold Time (LTC2970 Transmitting Data)
●
0
300
tSU,DAT
Data Setup Time (LTC2970 Receiving Data)
(Note 6)
●
tSP
Pulse Width of Spike Suppressed
(Note 6)
●
tSETUP_GPIO
GPIO_0 and GPIO_1 Setup Time
GPIO_0 and GPIO_1 input setup time
prior to the 26th rising SCL of an IO()
I2C read. These inputs must be valid and
stable by this time to be returned in the
IO() read result. (Note 6)
●
tHOLD_GPIO
GPIO_0 and GPIO_1 Hold Time
GPIO_0 and GPIO_1 input hold time
after the 26th rising SCL of an IO() I2C
read. These inputs must be held until
this amount of time has elapsed to be
returned in the IO() read result. (Note 6)
●
tOUT_GPIO
GPIO_0 and GPIO_1 Output Time
GPIO_0 and GPIO_1 output delay after
the 35th rising SCL of an I2C write. These
outputs will become high impedance or
begin driving low by this time. (Note 6)
●
900
100
ns
ns
ns
98
ns
2.5
μs
2.5
μs
2.5
μs
39
ms
Internal Timers
tTIMEOUT_SMB Stuck BUS Timer
The LTC2970 will release the I2C bus and
terminate the current command if the
command is not completed before this
amount of time has elapsed.
tSETUP_ADC
ADC Channel Setup Time
After selecting a new ADC channel, the
LTC2970 will wait this amount of time
to allow the analog input to settle before
beginning an ADC conversion.
304
μs
tTIMEOUT_
Tracking SYNC Failure Timer
LTC2970-1 Only: The LTC2970-1 will
abort a pending SYNC() command if a
tracking command is not received before
this amount of time has elapsed.
255
ms
Tracking IDAC Disconnect Delay
LTC2970-1 Only: After the tracking
algorithm asserts CPIO_CFG low, the
LTC2970-1 will delay disconnecting the
IDACs from the power supply feedback
nodes by this amount of time. Used while
tracking power supplies on.
32
ms
SYNC
tHOLD_TRACK
24
32
29701fc
5
LTC2970/LTC2970-1
ELECTRICAL CHARACTERISTICS
The ● denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C.
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
tSETUP_TRACK Tracking IDAC Disconnect Delay
LTC2970-1 Only: After the tracking
algorithm asserts CPIO_CFG high, the
LTC2970-1 will wait this amount of time
before starting to decrement Chn_a_
delay_track[9:0]. Used while tracking
power supplies off.
32
ms
tDEC_TRACK
LTC2970-1 Only: The LTC2970-1 changes
Chn_a_delay_track[9:0] at this rate.
88
μs/LSB
Tracking IDAC Decrement Rate
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All currents into device pins are positive; all currents out of device
pins are negative. All voltages are referenced to ground unless otherwise
specified.
Note 3: TUE (%) is defined as:
% Gain Error +
Note 4: Integral nonlinearity (INL) is defined as the deviation of a code
from a straight line passing through the actual endpoints (0V and 6V)
of the transfer curve. The deviation is measured from the center of the
quantization band.
Note 5: Nonlinearity is defined from the first code that is greater than or
equal to the maximum offset specification to code 255 (full-scale).
Note 6: Maximum capacitive load, CB, for SCL and SDA is 400pF. Data and
clock risetime (tr) and falltime (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 3V < VIO < 5.5V.
Note 7: This specification is guaranteed by design.
(INL • 500μV/LSB + VOS )
• 100
VIN
TIMING DIAGRAM
The I2C Bus Specification
SDA
tf
tLOW
tSU;DAT
tr
tf
tHD;STA
tSP
tr
tBUF
SCL
tHD;STA
START
CONDITION
tHD;DAT
tHIGH
tSU;STA
REPEATED START
CONDITION
tSU;STO
STOP
START
CONDITION CONDITION
29701 TD
29701fc
6
LTC2970/LTC2970-1
U W
TYPICAL PERFOR A CE CHARACTERISTICS
ADC Total Unadjusted Error
vs Temperature
ADC INL
BASED ON AVERAGE OF 15 PARTS
0.025 ASSEMBLED ON 1/8" THICK PCB
1V
0
ERROR (LSBs)
ERROR (%)
–0.025
1.8V
–0.050
2.5V
–0.075
3.3V
–0.100
1.00
2.0
0.75
1.5
0.50
1.0
0.5
0
ADC VIN = 5V
–0.125
ADC DNL
2.5
ERROR (LSBs)
0.050
–0.175
–50
0
25
50
TEMPERATURE (oC)
0
100
75
1
4
3
2
INPUT VOLTAGE (V)
5
–310
REJECTION (dB)
–315
–320
–325
–330
–25
0
25
50
TEMPERATURE (oC)
75
0
0
–10
–10
–20
–20
–30
–30
–40
–50
–60
–60
–80
–90
–100
100
10
1000
FREQUENCY AT VIN (Hz)
1
10000
0
5000 10000 15000 20000 25000 30000
FREQUENCY AT VIN (Hz)
29701 G05
29701 G06
Voltage Buffered IDAC DNL
Voltage Buffered IDAC INL
0.50
VIN = 0V
0.50
CHANNELS 0 AND 1 SHOWN
RIOUT0 = RIOUT1 = 10k7
1,000,000
0.25
CHANNELS 0 AND 1 SHOWN
RIOUT0 = RIOUT1 = 10k7
0.25
ERROR (LSBs)
ERROR (LSBs)
100000
6
–40
–90
ADC Noise Histogram
100
5
–50
–80
29701 G04
1000
2
4
3
INPUT VOLTAGE (V)
–70
–100
100
10,000
1
ADC Rejection vs Frequency
at VIN
–70
–335
–50
0
29701 G03
REJECTION (dB)
–305
VOS (MV)
–1.00
ADC Rejection vs Frequency
at VIN
ADC Zero Code Center Offset
Voltage vs Temperature
NUMBER OF READINGS
6
29701 G02
29701 G01
10,000,000
–0.25
–0.75
–1.0
–25
0
–0.50
–0.5
–0.150
0.25
0
–0.25
0
–0.25
10
1
–2
–1
0
1
OUTPUT CODE (LSBs)
2
29701 G07
–0.50
0
50
150
100
DAC CODE
200
250
29701 G08
–0.50
0
50
150
100
DAC CODE
200
250
29701 G09
29701fc
7
LTC2970/LTC2970-1
U W
TYPICAL PERFOR A CE CHARACTERISTICS
IDAC Output Current
vs Temperature
257.4
1.620
IDAC CODE = 'hff
RIOUT = 13kΩ
257.2
Voltage Buffered IDAC Load
Regulation Sourcing
3.500
IDAC CODE = 'h00
25oC
1.615
257.0
256.8
256.6
3.498
OUTPUT VOLTAGE (V)
OFFSET VOLTAGE (mV)
OUTPUT CURRENT (μA)
VOUTn Offset Voltage
vs Temperature
1.610
1.605
1.600
1.595
256.2
–50
1.590
–50
75
0
25
50
TEMPERATURE (°C)
100
90oC
–25
75
0
25
50
TEMPERATURE (oC)
100
VIOUTn = 3.5V
–2
0
–6
–4
CURRENT (mA)
–8
Voltage Buffered IDAC Transient
Response to 1LSB DAC Code Change
Voltage Buffered IDAC SoftConnect Transient Response
100k7 SERIES RESISTANCE ON VOUTn
RIOUT = 10k7
CODE 'h80
100k7 SERIES RESISTANCE ON VOUTn
RIOUT = 10k7
90oC
0.30
–10
29701 G12
29701 G11
Voltage Buffered IDAC Load
Regulation Sinking
VIOUT = 0.1V
3.494
3.490
29701 G10
0.35
3.496
3.492
256.4
–25
–45oC
0.20
–45oC
0.15
0.10
CODE 'h80
CODE 'h7f
10mV PER DIVISION
10mV PER DIVISION
OUTPUT VOLTAGE (V)
25oC
0.25
HIGH-Z
CONNECTED
0.05
0
0
2
4
6
10
8
CURRENT (mA)
5Ms PER DIVISION
1Ms PER DIVISION
29701 G13
Voltage Buffered IDAC Transient
Response During Transition from
On State to High-Z State
Temperature Sensor Error
vs Temperature
100k7 SERIES RESISTANCE ON VOUTn
RIOUT = 10k7
VDD Regulator Output Voltage
vs Temperature
1.5
4.945
1.0
4.944
VDD (V)
CONNECTED
0
–0.5
10Ms PER DIVISION
29701 G16
4.942
4.941
4.940
–1.0
–1.5
–50
V12VIN = 12V
IVDD = 0A
4.943
0.5
HIGH-Z
ERROR (oC)
10mV PER DIVISION
29701 G15
29701 G14
4.939
–25
0
25
50
TEMPERATURE (oC)
75
100
29701 G17
4.938
–50
–25
50
25
0
TEMPERATURE (oC)
75
100
29701 G18
29701fc
8
LTC2970/LTC2970-1
U W
TYPICAL PERFOR A CE CHARACTERISTICS
400
–100
300
–200
200
–25
NO LOAD ON VDD
SHORT-CIRCUIT CURRENT (mA)
0
100
–300
–45°C
–400
–500
0
25°C
90°C
–700
–45°C
–100
–200
–600
–800
VDD Regulator Short-Circuit
Current vs Temperature
VDD Regulator Line Regulation
ΔVDD (ppm)
ΔVDD (ppm)
VDD Regulator Load Regulation
25°C
–300
90°C
V12VIN = 12V
VDD = 0V
–30
–35
–400
V12VIN = 12V
0
–1
–2
–3
CURRENT (mA)
–4
–5
–500
8
9
10
29701 G19
10
12
V12VIN (V)
13
14
15
29701 G20
–40
–50
–25
0
25
50
TEMPERATURE (°C)
75
100
29701 G21
U
U
U
PI FU CTIO S
VIN0_AP (Pin 1): Positive CH0_A ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to
the input of the ADC. CH0_A can be configured to servo
IDAC0.
VIN0_AM (Pin 2): Negative CH0_A ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to
the input of the ADC. CH0_A can be configured to servo
IDAC0.
VIN0_BP (Pin 3): Positive CH0_B ADC Multiplexer Input. The
output of the differential, 7:1 multiplexer connects to the
input of the ADC. CH0_B is a voltage monitor input only.
VIN0_BM (Pin 4): Negative CH0_B ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to the
input of the ADC. CH0_B is a voltage monitor input only.
VIN1_AP (Pin 5): Positive CH1_A ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to
the input of the ADC. CH1_A can be configured to servo
IDAC1.
VIN1_AM (Pin 6): Negative CH1_A ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to
the input of the ADC. CH1_A can be configured to servo
IDAC1.
VIN1_BP (Pin 7): Positive CH1_B ADC Multiplexer Input. The
output of the differential, 7:1 multiplexer connects to the
input of the ADC. CH1_B is a voltage monitor input only.
VIN1_BM (Pin 8): Negative CH1_B ADC Multiplexer Input.
The output of the differential, 7:1 multiplexer connects to the
input of the ADC. CH1_B is a voltage monitor input only.
VDD (Pin 9): VDD Power Supply, Voltage Monitor Input,
and Internal 5V Regulator Output. The supply input range
is 4.5V to 5.75V. The VDD pin voltage can be connected
to the ADC through an internal mux. Bypass the VDD pin
to device ground with a 100nF capacitor (CVDD). If no 5V
input voltage supply is available, float the VDD pin and
power the LTC2970 from the 12VIN pin.
12VIN (Pin 10): 12V Power Supply and Voltage Monitor
Input. An internal regulator generates 5V from 12VIN. The
input range for 12VIN is 8V to 15V. Bypass this pin with a
100nF capacitor. The regulator’s output is connected to the
VDD pin. The 12VIN pin voltage can also be monitored by
the ADC through a 3:1 attenuator and the internal mux. If
no 12V supply input is available, tie the 12VIN to the VDD
pin and operate from 4.5V to 5.75V.
VOUT0 (Pin 11): CH0 Voltage Output. Buffered version of
IDAC0 output voltage.
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LTC2970/LTC2970-1
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U
PI FU CTIO S
VOUT1 (Pin 12): CH1 Voltage Output. Buffered version of
IDAC1 output voltage.
IOUT1 (Pin 13): IDAC1 Current Output. Connect a resistor
between this pin and the point-of-load ground for channel
1. The IDAC sources between 0 and 255μA.
IOUT0 (Pin 14): IDAC0 Current Output. Connect a resistor
between this pin and the point-of-load ground for channel
0. The IDAC sources between 0 and 255μA.
GPIO_1 (Pin 15): General Purpose Input or Open Drain
Digital Output. GPIO_1 can be configured as the IDAC
Fault or Faults output, a digital input, or an open-drain
digital output.
GPIO_0 (Pin 16): General Purpose Input or Open Drain
Digital Output. GPIO_0 can be configured as the voltage
monitor power-good or power-good bar output, a digital
input, or a programmable open-drain output. Power good
is the NOR of all instantaneous OV and UV faults; it does
not include IDAC faults.
⎯ ⎯L⎯E⎯R⎯T (Pin 17): Open Drain Digital Output. Connect the
A
SMBALERT signal to this pin. ⎯A⎯L⎯E⎯R⎯T is asserted low when
either IDAC0 or IDAC1 rails out (optional), or when one
of the monitored voltages ventures outside its UV and OV
thresholds (also optional).
SDA (Pin 19): Serial Bus Data Input and Output.
GPIO_CFG (Pin 20): GPIO Configuration Digital Input and
Open Drain Output. Pulling GPIO_CFG high will cause the
GPIO_0 and GPIO_1 open-drain outputs to automatically
assert low after a power-on reset. If GPIO_CFG is pulled
low, then GPIO_0 and GPIO_1 do not assert low after
power-up.
ASEL1 (Pin 21): Slave Address Select Bit 1. Tie this pin to
the VDD pin, ground, or float in order to select the address
location (see Table 2).
ASEL0 (Pin 22): Slave Address Select Bit 0. Tie this pin to
the VDD pin, ground, or float in order to select the address
location (see Table 2).
REF (Pin 23): Internal Reference Output or ADC Reference
Overdrive Input. The voltage at this pin determines the
full-scale input voltage of the delta-sigma ADC (VFULLSCALE = 6.65 • VREF , typically). An internal 3.5k resistor
decouples the reference output from this pin. Bypass this
pin to RGND with a 100nF capacitor (CREF).
RGND (Pin 24): Reference Ground. Connect to device
ground.
GND (Pin 25): Device Ground. Must be soldered to
ground.
SCL (Pin 18): Serial Bus Clock Input.
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LTC2970/LTC2970-1
W
BLOCK DIAGRA
5V REGULATOR
VIN
VOUT
12VIN 10
2R
0μA TO 255μA
IDAC0
8 BITS
R
14 IOUT0
VDD
VDD
9
+
12VP
CMP0
12VM
VDDP
GND 25
–
+
VDDM
VBUF0
VDD
11 VOUT0
–
TEMP
SENSOR
TSNSP
UVLO
POR
TSNSM
VIN0_AP
1
CH0_AP
VIN0_AM
2
CH0_AM
VIN0_BP
3
CH0_BP
VIN0_BM
4
CH0_BM
VIN1_AP
5
CH1_AP
VIN1_AM
6
CH1_AM
0μA TO 255μA
VIN1_BP
VIN1_BM
7
8
+
–
IDAC1
8 BITS
13 IOUT1
14-BIT
DELTA-SIGMA
A/D
+
CMP1
ADC
CLOCKS
CH1_BP
+
6.65X
(TYP)
CH1_BM
VDD
12 VOUT1
VBUF1
–
3.5k
7:1 MUX
–
REFERENCE
1.229V (TYP)
REF 23
RGND 24
20Ω
ADC_Results
MONITOR LIMITS
SERVO TARGETS
SCL 18
SDA 19
ASEL0 22
I2C BUS INTERFACE
(400kHz, SMBUS COMPATIBLE)
POR
SERVO CONTROLLER
GPIO_1 15
DAC SOFT CONNECT FUNCTION
SERVO FUNCTION
MONITOR FUNCTION
MANAGE FAULT REPORTING
WATCH DOG
TRACKING CONTROL (LT2970-1)
ALERT 17
GPIO_CFG 20
18
CLOCK
GENERATION
OSCILLATOR
ASEL1 21
GPIO_0 16
RAM
7
REGISTERS
I/O CONFIGURATION
IDAC0
IDAC1
ADC MONITOR
FAULT ENABLE
INSTANTANEOUS FAULTS
LATCHED FAULTS
2
POR
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LTC2970/LTC2970-1
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TABLE OF CO TE TS
(For Operations Sections)
1. LTC2970 Operation Overview .............................................................................................................................13
2. I2C Serial Digital Interface .................................................................................................................................14
3. Register Command Set.......................................................................................................................................15
4. Detailed I2C Command Register Descriptions ...................................................................................................16
5. Soft Connecting the LTC2970 to the Power Supply Feedback Node ..................................................................20
6. Hard Connecting the LTC2970 to the Power Supply Trim Pin ............................................................................20
7. Programming a Previously Connected IDAC ......................................................................................................21
8. Disconnecting the LTC2970 from the Power Supply Trim Pin ...........................................................................21
9. Tracking Power Supplies Overview (LTC2970-1 Only).......................................................................................21
10. Tracking Power Supplies On (LTC2970-1 Only) .................................................................................................21
11. Tracking Power Supplies Off (LTC2970-1 Only) .................................................................................................22
12. Continuous Power Supply Voltage Servo ...........................................................................................................23
13. One Time Power Supply Voltage Servo .............................................................................................................24
14. One Time Power Supply Voltage Servo with Repeat On Fault ..........................................................................24
15. Configuring ADC to Monitor Input Channels and Internal Temperature Sensor ................................................24
16. Generating and Monitoring Instantaneous Faults..............................................................................................25
17. Generating and Monitoring Latched Faults........................................................................................................26
18. General Purpose Input/Output Pins ....................................................................................................................27
19. Advanced Development Features .......................................................................................................................27
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LTC2970/LTC2970-1
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OPERATIO
1. LTC2970 Operation Overview
The LTC2970 is designed to control and monitor two
power supplies. The LTC2970’s superior accuracy allows
it to precisely servo each supply’s output voltage over a
wide range of operating conditions; increasing accuracy,
reducing power requirements and component costs. Margining may be performed with equal ease and precision.
The monitoring functions allow for increased reliability
by alerting a system host about incipient failures before
they occur. The seven channel ADC may also be used to
monitor current, temperature, and the 5V or optional 12V
supply.
The LTC2970’s unique architecture and control algorithm
have been especially tailored for power supply management. The soft connect feature allows the LTC2970 to begin
controlling a power supply without perturbing its initial
value. The delta-sigma ADC architecture was specifically
chosen to average out power-supply noise and allow the
LTC2970 to ignore fast transients. Unlike discrete time
DACs, the LTC2970’s continuous time, voltage buffered
IDAC is ideal for noise sensitive applications. The servo
algorithm limits the IDAC step size to one LSB per iteration
in order to minimize power supply transients. The point
of load ground reference for the IDAC outputs minimize
errors that would otherwise occur in a power system that
experiences ground bounce. By selecting two resistor
values, the user can choose the appropriate resolution
while providing an important hardware range limit beyond
which the supply may not be driven. The servo on fault
option allows the LTC2970 to further reduce output voltage
disturbances by only stepping the IDAC when the output
voltage drifts outside of a user programmable window.
The LTC2970 powers up in a high impedance state and
will not interfere with default power supply operation.
Similarly, powering down the LTC2970 will restore its
high impedance state.
All communication with the LTC2970 is performed over
an industry standard I2C bus. The LTC2970 I2C interface
also meets all SMBus setup times, hold times, and timeout
requirements. The ALERT pin may be used to signal that
one or more of the fourteen configurable fault limits have
been reached. Each fault may be individually masked. The
I2C interface supports word reads, word writes and the
SMBus Alert Response Address protocol. Two general
purpose IO pins may be used to provide additional fault
information or user defined system control. Powering down
the LTC2970 will not interfere with I2C operation.
The LTC2970-1 enables power supply tracking and sequencing with the addition of a few external components.
A special global address and synchronization command
allow multiple LTC2970-1’s to track and sequence multiple
pairs of power supplies.
The LTC2970 can perform the following operations:
• Accept all programming commands and report status
over the I2C or SMBus bus.
• Command each voltage buffered IDAC to connect to the
corresponding power supply’s feedback node through
an external resistor using the IDAC code that most
closely approximates the feedback node’s regulation
voltage (Soft Connect).
• Command each voltage buffered IDAC output to connect
to the corresponding power supply’s feedback node
through an external resistor with a user-selected IDAC
code (Hard Connect).
• Change the code of a previously connected IDAC.
• Disconnect each voltage buffered IDAC output from the
power supply’s feedback node.
• LTC2970-1 Only: Track two power supplies up or down.
Multiple LTC2970-1’s can be configured to track simultaneously or in a sequence.
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LTC2970/LTC2970-1
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OPERATIO
• Continuously servo one or both supplies to a programmed voltage.
• Perform a one-time servo of one or both supplies to a
programmed voltage and hold the servo codes in the
controlling IDAC.
• Perform a one time servo of one or both supplies to
a programmed voltage and hold the code(s) in the
controlling IDAC(s) until over/under voltage monitoring detects a fault, at which point a control bit may be
used to allow the LTC2970 to servo back to the initial
voltage target.
• Select any combination of seven possible ADC channels
to be monitored by the ADC.
• Generate instantaneous faults based on user programmable over-voltage and under-voltage limits and fixed
IDAC limits. The status of OR’d voltage limit faults and
IDAC faults may be output over GPIO_0 and GPIO_1,
respectively.
• Enable instantaneous faults to set associated latched
faults using the FAULT_EN register. The status of OR’d
latched faults may be signalled using ALERT.
• Configure the GPIO_0 and GPIO_1 pins to act as inputs
or outputs.
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 LTC2970 I2C interface is SMBus compatible; it meets
all SMBus setup times, hold times and timeout requirements.
The LTC2970 is a receive-only (slave) device. The LTC2970
can signal the host through the SMBALERT protocol that it
wants to talk by asserting ALERT low. The LTC2970 supports the three I2C protocols summarized in Table 1.
Slave Address
The LTC2970 can respond to one of nine 7-bit addresses.
The two slave address select pins (ASEL1 and ASEL0) are
programmed by the user and determine the slave address,
as shown in Table 2.
The LTC2970 also supports the ARA address and a global
address that allows multiple LTC2970s to be programmed
with the same data simultaneously, as shown in Table 3.
Table 1. Supported I2C Command Types
READ DATA WORD:
S:ADR:W:A:CMD:A:Sr:ADR:R:A:DATA:A:DATA:NACK:P
WRITE DATA WORD:
S:ADR:W:A:CMD:A:DATA:A:DATA:A:P
2.
I2C Serial Digital Interface
The LTC2970 communicates with a host (master) using
the 2-wire, I2C serial bus interface. The Timing Diagram
shows the timing relationship of the signals on the bus.
ALERT RESPONSE
S:ARA:R:A:ADR:NACK:P:
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14
LTC2970/LTC2970-1
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OPERATIO
Table 3. Special LTC2970 Addresses
Table 2. LTC2970 Address Table
ADDRESS[7:0]
(R/W = 0)
ADDRESS[7:1]
ASEL1
ASEL0
8’hB8
7’h5C
L
L
8’hBA
7’h5D
L
F
8’hBC
7’h5E
L
H
8’hBE
7’h5F
F
L
8’hD6
7’h6B
F
F
8’hD8
7’h6C
F
H
8’hDA
7’h6D
H
L
8’hDC
7’h6E
H
F
8’hDE
7’h6F
H
H
ADDRESS[7:0] ADDRESS[7:1] FUNCTION
(R/W = 0)
ARA
8’h18
7’h0C
This is the standard Alert
Response Address for all
SMBus devices. This address is
independent of the value of the
ASEL1 and ASEL0 pins.
Global
8’hB6
7’h5B
This a global address to which
all LTC2970s will respond. This
address is independent of the
value of the ASEL1 and ASEL0
pins.
L: VASELn < VIL_ASEL F: ASELn Floating H: VASELn > VIH_ASEL
3. Register Command Set
COMMAND FUNCTION
DESCRIPTION
R/W
DATA
LENGTH
COMMAND
BYTE VALUE
FAULT()
FAULT_EN()
Instantaneous Fault Status For All Channels
Read Only
16 Bits
‘h00
Enable For All Latched Faults and Servo On Fault
Read/Write
16 Bits
‘h08
FAULT_LA_INDEX()
Index to All Latched Faults
Read Only
16 Bits
‘h10
FAULT_LA()
Latched Fault Status For All Channels
Read Only
16 Bits
‘h11
IO()
IO Control and Status Register
Read/Write
16 Bits
‘h17
ADC_MON()
Control Register For Selecting ADC Channels to Monitor
Read/Write
16 Bits
‘h18
*SYNC()
Control Register For Synchronizing Tracking Across Multiple Devices
Read/Write
16 Bits
‘h1F
VDD_ADC()
VDDIN ADC Conversion Result Register
Read Only
16 Bits
‘h28
VDD_OV()
VDDIN Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h29
VDD_UV()
VDDIN Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h2A
V12_ADC()
12VIN ADC Conversion Result Register
Read Only
16 Bits
‘h38
V12_OV()
12VIN Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h39
V12_UV()
12VIN Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h3A
CH0_A_ADC()
CH0_A ADC Conversion Result Register
Read Only
16 Bits
‘h40
CH0_A_OV()
CH0_A Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h41
CH0_A_UV()
CH0_A Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h42
CH0_A_SERVO()
CH0_A Voltage Servo Control Register
Read/Write
16 Bits
‘h43
CH0_A_IDAC()
CH0_A IDAC Control Register
Read/Write
16 Bits
‘h44
*CH0_A_IDAC_TRACK()
CH0_A IDAC Track Final Value Register
Read/Write
16 Bits
‘h45
*CH0_A_DELAY_TRACK()
CH0_A IDAC Track Delay Register
Read/Write
16 Bits
‘h46
CH0_B_ADC()
CH0_B ADC Conversion Result Register
Read Only
16 Bits
‘h48
CH0_B_OV()
CH0_B Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h49
CH0_B_UV()
CH0_B Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h4A
CH1_A_ADC()
CH1_A ADC Conversion Result Register
Read Only
16 Bits
‘h50
CH1_A_OV()
CH1_A Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h51
CH1_A_UV()
CH1_A Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h52
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LTC2970/LTC2970-1
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OPERATIO
3. Register Command Set (Cont.)
COMMAND FUNCTION
DESCRIPTION
R/W
DATA
LENGTH
COMMAND
BYTE VALUE
CH1_A_SERVO()
CH1_A Voltage Servo Control Register
Read/Write
16 Bits
‘h53
CH1_A_IDAC()
CH1_A IDAC Control Register
Read/Write
16 Bits
‘h54
*CH1_A_IDAC_TRACK()
CH1_A IDAC Track Control Register
Read/Write
16 Bits
‘h55
*CH1_A_DELAY_TRACK()
CH1_A IDAC Track Delay Register
Read/Write
16 Bits
‘h56
CH1_B_ADC()
CH1_B ADC Conversion Result Register
Read Only
16 Bits
‘h58
CH1_B_OV()
CH1_B Over-Voltage Monitor Control Register
Read/Write
16 Bits
‘h59
CH1_B_UV()
CH1_B Under-Voltage Monitor Control Register
Read/Write
16 Bits
‘h5A
TEMP_ADC()
Temperature ADC Conversion Result Register
Read/Write
16 Bits
‘h68
RESERVED()
All other commands are reserved for future expansion and should not be
written or read.
Read/Write
16 Bits
‘hXX
*LTC2970-1 Only. LTC2970 will not acknowledge these commands.
4. Detailed I2C Command Register Descriptions
FAULT_EN: Fault Enabling Register – Read/Write
FAULT: Instantaneous Fault Register – Read
BIT(s)
SYMBOL
OPERATION
BIT(s)
b[0]
Fault_en_ch0_a_ov
b[1]
Fault_en_ch0_a_uv
0 = The associated bit in the
FAULT_LA register will always be 0.
(default)
SYMBOL
b[0]
Fault_ch0_a_ov
b[1]
Fault_ch0_a_uv
b[2]
Fault_ch0_a_idac
b[3]
Fault_ch0_b_ov
b[4]
Fault_ch0_b_uv
b[5]
Fault_ch1_a_ov
b[6]
Fault_ch1_a_uv
b[7]
Fault_ch1_a_idac
b[8]
Fault_ch1_b_ov
b[9]
Fault_ch1_b_uv
b[10]
Fault_vdd_ov
b[11]
Fault_vdd_uv
b[12]
b[13]
OPERATION
0 = The associated channel is clear of
instantaneous faults.
b[2]
Fault_en_ch0_a_idac
1 = The associated channel has an
instantaneous fault.
b[3]
Fault_en_ch0_b_ov
b[4]
Fault_en_ch0_b_uv
The reported faults are instantaneous
and not latched. When used in
conjunction with latched faults they
may indicate faults that are transient in
nature.
b[5]
Fault_en_ch1_a_ov
b[6]
Fault_en_ch1_a_uv
b[7]
Fault_en_ch1_a_idac
b[8]
Fault_en_ch1_b_ov
b[9]
Fault_en_ch1_b_uv
b[10]
Fault_en_vdd_ov
b[11]
Fault_en_vdd_uv
b[12]
Fault_en_v12_ov
b[13]
Fault_en_v12_uv
b[14]
Fault_en_ch0_a_servo
b[15]
Fault_en_ch1_a_servo
Fault_v12_ov
Fault_v12_uv
b[15:14] Reserved
Always Returns 0
1 = Instantaneous faults reported in
the FAULT register will set associated
bit in the FAULT_LA register.
0 = Do not re-servo CH0_A in
response to instantaneous OV or UV
fault.
1 = Repeat a one time servo of CH0_A
in response to instantaneous OV or
UV fault. CH0_A must have servo
operation enabled with Ch0_a_idac_
servo_repeat set low, and Adc_mon_
ch0_a set high.
0 = Do not re-servo CH1_A in
response to instantaneous OV or UV
fault.
1 = Repeat a one time servo of CH1_A
in response to instantaneous OV or
UV fault. CH1_A must have servo
operation enabled with Idac_ch1_a_
servo_repeat set low, and Adc_mon_
ch1_a set high.
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LTC2970/LTC2970-1
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OPERATIO
4. Detailed I2C Command Register Descriptions
(Cont.)
FAULT_INDEX: Latched Fault Index Register – Read
BIT(s)
SYMBOL
OPERATION
b[0]
Fault_la_index
0 = All faults indicated by FAULT_LA
are clear.
IO: Input/Output Data and General Purpose Control Register
– Read/Write unless specified otherwise.
BIT(s)
SYMBOL
OPERATION
b[1:0]
Io_cfg_0[1:0]
Io_cfg_0[1:0] is used to configure the function of
the GPIO_0 pin and IO(Io_gpio_0).
00: Io_gpio_0 = GPIO_0 = Power_good. Power_
good asserts high if there are no instantaneous
over-voltage or under-voltage faults.
1 = One or more faults indicated by
FAULT_LA are set.
01: Io_gpio_0 = GPIO_0 = Power_good_bar.
Power_good_bar is the complement of
Power_good.
This register allows a summary of all
latched faults to be viewed in a single
read without resetting latched faults.
b[15:1]
Reserved
10: GPIO_0 is a general-purpose open-drain
output and mirrors the value written to Io_gpio_0
(default).
Always Returns 0
11: GPIO_0 is a general-purpose digital input
with Io_gpio_0 = GPIO_0
FAULT_LA: Latched Fault Register – Read
BIT(s)
SYMBOL
OPERATION
b[0]
Fault_la_ch0_a_ov
b[1]
Fault_la_ch0_a_uv
0 = The associated channel is clear of
faults.
b[2]
Fault_la_ch0_a_idac
b[3]
Fault_la_ch0_b_ov
b[4]
Fault_la_ch0_b_uv
b[5]
Fault_la_ch1_a_ov
b[6]
Fault_la_ch1_a_uv
b[7]
Fault_la_ch1_a_idac
b[8]
Fault_la_ch1_b_ov
b[9]
Fault_la_ch1_b_uv
b[10]
Fault_la_vdd_ov
b[11]
Fault_la_vdd_uv
b[12]
Fault_la_v12_ov
b[13]
Fault_la_v12_uv
b[15:14] Reserved
b[3:2]
Io_cfg_1[1:0]
00: Io_gpio_1 = GPIO_1 = Idac_fault.
Idac_fault asserts if either IDAC value is faulted
(Chn_idac[7:0] = 8’h00 or 8’hff)
1 = The associated channel has faulted
and is enabled.
The latched faults are set and held
when the associated channel's
instantaneous fault has occured with
faults enabled. Clearing the enable bit
for the associated channel in FAULT_EN
will immediately clear its corresponding
latched fault bit.
All latched channel faults are cleared
when this register is read. They may
be set again if the instantaneous
fault condition and fault_en have not
changed.
Io_cfg_1[1:0] is used to configure the function
of the GPIO_1 pin and IO(Io_gpio_1).
01: Io_gpio_1 = GPIO_1 = Idac_fault_bar.
Idac_fault_bar is the complement of Idac_fault.
10 = GPIO_1 is a general-purpose opendrain output and mirrors the value written to
Io_gpio_1 (default).
11 = GPIO_1 is a general-purpose digital input
with Io_gpio_1 = GPIO_1
b[4]
Io_gpio_0
See Io_cfg_0.
If the GPIO_CFG pin is pulled-high during a
power on reset, Io_gpio_0 is cleared and the
GPIO_0 open-drain output will assert low.
b[5]
Io_gpio_1
See Io_cfg_1.
If the GPIO_CFG pin is pulled-high during a
power on reset, Io_gpio_1 is cleared and the
GPIO_1 open-drain output will assert low.
b[6]
Io_alertb
Mirrors the value of the ALERT pin.
Read only.
b[7]
Io_alertb_enb
Always Returns 0
1 = ALERT pin never asserts (default).
0 = ALERT pin asserts low when one or more
FAULT_LA bits are set.
b[8]
Io_i2c_adc_
wen
1 = Special test mode that inhibits ADC from
writing to ADC result register and allows user
to update registers over the I2C serial interface.
0 = Normal operation (default).
b[9]
Io_gpio_cfg
Read only. GPIO_CFG digital input and opendrain output. Reading this bit returns the
current state of the GPIO_CFG pin voltage.
b[10]
Io_track_start
Writing a 1 to this bit will start tracking all
enabled channels. Returns a 1 when tracking
is pending (LTC2970-1). Reserved on LTC2970
and always returns 0.
b[15:11] Reserved
Always Returns 0
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4. Detailed I2C Command Register Descriptions
(Cont.)
ADC_MON: ADC Monitoring Mux Control Register – Read/Write
VDD_ADC, V12_ADC, CH0_A_ADC, CH0_B_ADC, CH1_A_ADC,
CH1_B_ADC, and TEMP_ADC: ADC Conversion Result Registers
– Read Only Unless Specified Otherwise
BIT(s)
SYMBOL
OPERATION
b[14:0]
Vdd_adc[14:0]
Measured data from ADC conversion.
0 = ADC will not convert associated
channel. (Default)
V12_adc[14:0]
1 = ADC will continuously convert
associated channel.
Ch0_b_adc[14:0]
Ch1_a_adc[14:0]
'h4000 corresponds to negative fullscale input voltage.
'h0000 corresponds to 0V.
'h3fff corresponds to full-scale input
voltage.
Ch1_b_adc[14:0]
2’s complement format, b[14] = sign.
Temp_adc[14:0]
Read/Write when Io_i2c_adc_wen = 1.
BIT(s)
SYMBOL
OPERATION
b[0]
Adc_mon_vdd
b[1]
Adc_mon_v12
b[2]
Adc_mon_ch0_a
b[3]
Adc_mon_ch0_b
b[4]
Adc_mon_ch1_a
b[5]
Adc_mon_ch1_b
b[6]
Adc_mon_temp
b[15:7]
Reserved
Ch0_a_adc[14:0]
Default value is undefined.
Always Returns 0
b[15]
Vdd_adc_new
V12_adc_new
SYNC: Tracking Synchronization Control Register – Read/Write
LTC2970-1 Only
BIT(s)
SYMBOL
OPERATION
b[0]
Sync_track
Write
0 = Do not synchronize.
Ch0_a_adc_new
Ch0_b_adc_new
1 = The LTC2970-1 is synchronized for
tracking.
Use of the global address will allow
the synchronization status of multiple
LTC2970-1s to be verified in a single
read; since a one can only be returned
if all LTC2970-1s are synchronized. The
IO_track_start command may then be
issued with the same global address
to begin synchronized tracking across
multiple ICs.
b[15:1]
Reserved
Always Returns 0
0 = Previously read data. (Default)
Ch1_a_adc_new
Ch1_b_adc_new
Temp_adc_new
1 = Synchronize all tracking enabled
registers to the same starting point.
Read
0 = The LTC2970-1 is not synchronized
for tracking (default).
1 = The ADC has updated the
associated result register since the last
time the data was read.
VDD_OV, V12_OV, CH0_A_OV, CH0_B_OV, CH1_A_OV, CH1_B_
OV: Over Voltage Limit Registers – Read/Write
BIT(s)
SYMBOL
OPERATION
b[14:0]
Vdd_ov[14:0]
ADC over-voltage threshold limit.
V12_ov[14:0]
Ch1_a_ov[14:0]
The associated instantaneous over
voltage fault is asserted if the channel’s
ADC result is greater than this limit.
Code 'h3fff disables OV threshold
detect feature for that channel.
Ch1_b_ov[14:0]
2’s complement format, b[14] = sign.
Ch0_a_ov[14:0]
Ch0_b_ov[14:0]
Default value is undefined.
b[15]
Reserved
Always Returns 0
VDD_UV, V12_UV, CH0_A_UV, CH0_B_UV, CH1_A_UV, CH1_B_
UV: Under Voltage Limit Registers – Read/Write
BIT(s)
SYMBOL
OPERATION
b[14:0]
Vdd_uv[14:0]
ADC under-voltage threshold limit.
V12_uv[14:0]
Ch1_a_uv[14:0]
The associated instantaneous under
voltage fault is asserted if the channel’s
ADC result is greater than this limit.
Code 'h4000 disables UV threshold
detect feature for that channel.
Ch1_b_uv[14:0]
2’s complement format, b[14] = sign.
Ch0_a_uv[14:0]
Ch0_b_uv[14:0]
Default value is undefined.
b[15]
Reserved
Always Returns 0
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4. Detailed I2C Command Register Descriptions
(Cont.)
b[10]
Ch0_a_idac_pol
0 = Use this setting when
increasing VOUTn causes
(VINn_AP-VINn_AM) to decrease.
Inverting configuration common
to DC/DC converters with external
feedback networks.
Ch1_a_idac_pol
CH0_A_SERVO, CH1_A_SERVO: Voltage Servo Control
Registers – Read/Write
BIT(s)
SYMBOL
OPERATION
b[14:0]
Ch0_a_servo[14:0]
During servo operation
Ch1_a_servo[14:0]
Chn_a_idac[7:0] output current is
stepped to force Chn_a_adc[14:0]
code to equal target code stored in
Chn_a_servo[14:0].
2’s complement format, b[14] = sign
1 = Use this setting when
increasing VOUTn causes
(VINn_AP-VINn_AM) to increase.
Non-inverting configuration
common to DC/DC converters
with trim pins.
b[11]
Ch1_a_idac_servo_repeat
Default value is undefined.
b[15]
Ch0_a_servo_en
0 = Chn_a servo disabled (default).
Ch1_a_servo_en
1 = Chn_a servo enabled.
CH0_A_IDAC, CH1_A_IDAC: IDAC Control/Data Registers –
Read/Write
BIT(s)
SYMBOL
OPERATION
b[7:0]
Ch0_a_idac[7:0]
Chn_a IDAC data value.
Ch1_a_idac[7:0]
b[8]
0 = During servo operation, servo
Chn_a until the measured result
is stable and matches the target
code.
1 = During servo operation,
continuously servo Chn_a to the
target code.
b[15:12] Reserved
Always Returns 0
CH0_A_IDAC_TRACK and CH1_A_IDAC_TRACK: IDAC Tracking
data and control registers – Read/Write
LTC2970-1 Only
Ch0_a_idac_en
0 = VOUTn output tri-stated.
BIT(s)
SYMBOL
OPERATION
Ch1_a_idac_en
1 = VOUTn output enabled.
b[7:0]
Ch0_a_idac_
track[7:0]
Final target value for of Chn_a_
idac[7:0]. During tracking, Chn_a_
idac[7:0] is incremented/decremented
by 1 until it is equal to this value.
There are two ways to enable
VOUTn.
1) When Chn_a_idac_en is set
high with Chn_a_idac_con low,
the LTC2970 will perform a soft
connect. During a soft connect,
the VOUTn voltage buffer output
will not be connected to the VOUTn
pin until the internal algorithm
has servo’d the voltage at the
IDACn pin to match the VOUTn
pin voltage. Resolution is one
Chn_a_idac LSB.
2) When Chn_a_idac_en is
enabled with Chn_a_idac_con
high, the LTC2970 will perform
a hard connect. The VOUTn
voltage buffer will be immediately
connected to the VOUTn pin.
b[9]
Ch0_a_idac_servo_repeat
Ch0_a_idac_con
Ch1_a_idac_con
Ch1_a_idac_
track[7:0]
b[8]
Ch0_a_idac_track_en 0 = inhibit tracking of Chn_a_idac[7:0].
b[15:9]
Reserved
Ch1_a_idac_track_en 1 = enable tracking of Chn_a_idac[7:0]
Always Returns 0
CH0_A_DELAY_TRACK and CH1_A_DELAY_TRACK: IDAC
Tracking delay register – Read/Write
LTC2970-1 Only
BIT(s)
SYMBOL
OPERATION
b[9:0]
Ch0_a_delay_track[9:0]
Ch1_a_delay_track[9:0]
Delay used to synchronize or offset
tracking events.
Reserved
Always Returns 0
b[1510]
0 = VOUTn is not enabled or
has been enabled but is not yet
connected to the output of the
CHn voltage buffer. (Default)
1 = VOUTn is enabled and has been
connected to the output of the
CHn voltage buffer.
See Chn_a_idac_en for additional
information.
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5. Soft Connecting the LTC2970 to the Power Supply
Feedback Node
The soft connect feature allows the LTC2970 to connect to
the power supply’s feedback node with minimal disturbance
to the supply’s output voltage. This is accomplished by
comparing the buffered voltage of IOUTn to the voltage at
VOUTn and incrementing or decrementing Chn_a_idac[7:0]
until the comparator output (COMPn) changes. The value
of Chn_a_idac[7:0] when the comparator transitions is the
appropriate value for a soft connect. The voltage buffer
output is only connected to VOUTn if the IDAC reaches this
soft connect value without generating an instantaneous
IDAC fault (Fault_chn_a_idac).
Soft-Connect Procedure:
Determine the appropriate polarity for Chn_a_idac_pol.
Select Chn_a_idac_pol = 1 if incrementing VOUTn causes
differential voltage (VINn_AP – VINn_AM) to increase.
When properly programmed, lowering the value in Chn_
a_idac[7:0] will always cause the output of the controlled
power supply to decrease.
Ensure that the channel’s IDAC is not currently enabled for
connection, i.e., the Chn_a_idac_en bit must be 0.
Update CHn_A_IDAC() with Chn_a_idac_pol, Chn_a_idac_
con = 0, Chn_a_idac_en = 1, and Chn_a_idac[7:0] = 0x80.
The value programmed into Chn_a_idac[7:0] is ignored
and Chn_a_idac[7:0] is initially set to 8’h80.
The LTC2970 will now ramp Chn_a_idac[7:0] while monitoring the output of the soft connect comparator. If the soft
connect comparator trips, the LTC2970 will connect the
output of VBUFn to VOUTn and set Chn_a_idac_con high.
If the soft connect comparator does not trip before the
IDAC value reaches ‘h00 or ‘hFF, then the soft connection
will fail, an IDAC fault will be indicated (Fault_chn_a_idac),
and Chn_a_idac_con will remain low.
Soft-Connect Rules:
When both channels are requesting a soft connect, channel 0 has priority.
Soft connect requests will be ignored and the user will not
be able to change Chn_a_idac_pol or Chn_a_idac[7:0] if
the LTC2970 is servicing a previously issued soft connect
on that channel or the previously issued soft connect failed
with an IDAC fault (Fault_chn_a_idac = 1). Recall that the
Chn_a_idac_en bit must initially have been set to 0.
LTC2970-1 Only: Soft connect requests will be ignored
and the user will not be able to change Chn_a_idac_pol or
Chn_a_idac[7:0] if GPIO_CFG is high and either GPIO_0
or GPIO_1 are high.
LTC2970-1 Only: Soft connect requests will be ignored and
the user will not be able to change the Chn_a_idac_pol bit
if there is a pending tracking operation.
6. Hard Connecting the LTC2970 to the Power Supply
Trim Pin
The hard connect feature allows the LTC2970 to bypass the
soft connect algorithm and connect directly to the power
supply’s feedback node using the value programmed into
Chn_a_idac[7:0]. This feature is useful for systems that
have calculated or measured an acceptable voltage at which
to connect the IDAC’s buffered voltage VBUFn to VOUTn.
Hard Connect Procedure:
Determine the appropriate polarity for Chn_a_idac_pol.
Select Chn_a_idac_pol = 1 if incrementing VOUTn causes
(VINn_AP – VINn_AP) to increase. When properly programmed, lowering the value in the IDAC will always cause
the output of the controlled power supply to decrease.
Determine the value for Chn_a_idac[7:0]. The values ‘h00
or ‘hff are allowed, but they will trip the IDAC’s fault bit
(Fault_chn_a_idac = 1).
When the IDAC is already connected, the value Chn_a_
idac[7:0] and Chn_a_idac_pol will be programmed into the
IDAC provided all other conditions are met. See “Programming a Previously Connected Current DAC” for details
Update CHn_A_IDAC() with Chn_a_idac_pol, Chn_a_idac_
con = 1, Chn_a_idac_en = 1, and Chn_a_idac[7:0].
Hard Connect Rules:
Hard connect requests will be ignored and the user will not
be able to change Chn_a_idac_pol, Chn_a_idac_con or
Chn_a_idac[7:0] if the LTC2970 is servicing a previously
issued soft connect on that channel or the previously issued
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OPERATIO
soft connect failed with an IDAC fault (Fault_chn_a_idac =
1). Recall that a new hard connection requires the previous
value of Chn_a_idac_en = 0.
LTC2970-1 Only: Hard connect requests will be ignored
and the user will not be able to change Chn_a_idac_pol,
Chn_a_idac_con or Chn_a_idac[7:0] if GPIO_CFG is high
and either GPIO_0 or GPIO_1 are high.
LTC2970-1 Only: Hard connect requests will be ignored and
the user will not be able to change Chn_a_idac_pol, Chn_a_
idac_con or Chn_a_idac[7:0] if there is a pending tracking
operation.
7. Programming a Previously Connected IDAC
8. Disconnecting the LTC2970 from the Power Supply
Trim Pin
VOUTn can be placed in a high impedance state simply by
clearing the Chn_a_idac_en bit. In order to minimize the
resulting disturbance to the power supply voltage, the
IDAC code should not be changed from its current value
when clearing the Chn_a_idac_en bit. This is not an issue
if the channel’s associated servo_en bit is high.
Disconnect Procedure:
Update CHn_IDAC() with Chn_a_idac_en set low.
The LTC2970 will immediately disconnect the buffered
IOUTn from VOUTn.
The LTC2970 IDAC’s may be programmed after they have
been connected with a soft connect or a hard connect
provided a servo operation is not enabled on the associated channel.
Disconnect Rules:
Procedure:
Determine the value for Chn_a_idac[7:0]. The values
‘h00 or ‘hff are allowed, but will trip the IDAC’s fault bit
(Fault_chn_a_idac = 1).
LTC2970-1 Only: Chn_a_idac_en may not be changed if
the feedback node connection is configured for tracking.
Tracking is enabled when GPIO_CFG is high and either
GPIO_0 or GPIO_1 are high.
Verify that the IDAC is already connected, and that
Chn_a_idac_con is high.
9. Tracking Power Supplies Overview (LTC2970-1
Only)
Ensure that servo mode is not enabled for the channel
being programmed. Chn_a_servo_en must be low. This
requirement prevents the user from interfering with a
previously requested servo operation.
The LTC2970-1 tracking feature allows the I2C interface
to initiate a controlled power up or power down of two
or more supplies (Figure 2 shows a typical LTC2970-1
application circuit). Multiple LTC2970-1’s with different
addresses may be simultaneously programmed using
the LTC2970 group address and the SYNC() command.
Tracking is enabled when GPIO_CFG is pulled high and
either GPIO_0 or GPIO_1 are high.
Update the CHn_A_IDAC() register with Chn_a_idac_pol,
Chn_a_idac_con = 1, Chn_a_idac_en = 1, and Chn_a_
idac[7:0].
Note: Care should be taken to preserve the current value
of the Chn_a_idac_pol bit, since the LTC2970 does not
prevent the user from changing this value when writing
to the IDAC control registers.
Rules:
Setting Chn_a_idac_con to zero will not disconnect the
DAC unless Chn_a_idac_en is also set low.
All Hard Connect rules apply.
Clearing Chn_a_idac_con with Chn_a_idac_en high will
not disconnect the IDAC. Only setting Chn_a_idac_en low
will clear Chn_a_idac_con.
10. Tracking Power Supplies On (LTC2970-1 Only)
The LTC2970-1 tracking feature allows the I2C to initiate
a controlled power up of two or more supplies.
Procedure: This procedure describes all the steps necessary to track up two or more power supplies. Steps that
require I2C interaction are prefixed with the required I2C
command function.
Power-up the LTC2970-1 with GPIO_CFG pulled high.
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OPERATIO
This causes open-drain outputs GPIO_1 and GPIO_0 to
automatically pull the power supplies’ run/soft-start pins
to ground.
CHn_A_IDAC(): Hard connect Chn_a_idac[7:0] with a value
that forces the power supplies off when GPIO_CFG = 1.
Verify that Chn_a_idac_pol is at the appropriate value.
CHn_A_IDAC_TRACK(): Set Chn_a_idac_track_en = 1,
and set the Chn_a_idac_track[7:0] target value to the
code that causes VOUTn to most closely approximate the
corresponding power supply’s feedback node voltage
when it is in regulation.
CHn_A_DELAY_TRACK(): Set the value by which the
incrementing of IDACn should be delayed with respect to
the start of tracking event. This controls whether the power
supplies track up coincidentally or sequentially.
IO(): Release the run/soft-start pins by programming
io_gpio_n = 1. This will enable the power supplies without
allowing their outputs to move since these are held low
by Chn_a_idac[7:0]. Wait until power supplies have had
sufficient time to start running before starting tracking.
SYNC(): Optional command that allows multiple LTC29701’s to be synchronized for tracking. Writing Sync_track
= 1 will allow the LTC2970-1 to finish its current ADC
conversion before having it wait to receive io_track_start
= 1. The LTC2970-1 will timeout this wait command after
tTIMEOUT_SYNC. Reading back Sync_track = 1 using the
global address will ensure all LTC2970-1’s are synchronized
before proceeding with the tracking operation.
IO(): Set Io_track_start = 1 and keep the run/soft-start pins
enabled. Use the global I2C address to simultaneously track
up power supplies across multiple LTC2970-1’s.
LTC2970-1 response: For each tracking enabled channel,
the LTC2970-1 will decrement the CHn_A_delay_track
counter at a rate of tDEC_TRACK. As soon as a channel’s
tracking counter reaches zero, the LTC2970-1 will begin
stepping the value of Chn_a_idac[7:0] by one count until
the final value of Chn_a_idac_track[7:0] is reached, at which
point Chn_a_idac_track_en is de-asserted. When the final
value is reached for all channels, GPIO_CFG is asserted
low. After a time delay of tHOLD_TRACK, Chn_a_idac_en is
de-asserted.
Power-Up Tracking Rules:
Tracking cannot begin if Chn_a_idac_con is not connected.
This condition is met when the previous procedure is
followed.
Chn_a_idac_track_pol, Chn_a_idac_track_en, and ch0_
idac[7:0] updates will be ignored after IO(Io_track_start)
is asserted until tracking is complete or whenever tracking
is pending, i.e., GPIO_CFG pulled high with either GPIO_0
or GPIO_1 asserted pulled high.
11. Tracking Power Supplies Off (LTC2970-1 Only)
The LTC2970-1 tracking feature allows the I2C to initiate
a controlled power down of two or more supplies.
Procedure: This procedure describes all steps necessary
to track down two or more power supplies. Steps that
require I2C interaction are prefixed with the required I2C
command function.
CHn_IDAC(): Disable the IDAC’s for each tracking enabled
channel (Chn_a_idac_en = 0). Ensure Chn_a_idac_pol is
at the appropriate value.
CHn_IDAC_TRACK(): Select the channels to be tracked
by setting Chn_a_idac_track_en = 1, and set the target
value for each Chn_a_idac_track[7:0] to that which forces
the supply off.
CHn_A_DELAY_TRACK(): Set the value by which the
decrementing of that channel’s DAC should be delayed
with respect to the start of the tracking event. This controls whether the supplies track down coincidentally or
sequentially.
SYNC(): Optional command that allows multiple LTC29701’s to be synchronized for tracking. Writing Sync_track
= 1 will allow the LTC2970-1 to finish its current ADC
conversion before having it wait to receive io_track_start
= 1. The LTC2970-1 will timeout this wait command after
tTIMEOUT_SYNC. Reading back Sync_track = 1 using the
global address will ensure all LTC2970’s are synchronized
before proceeding with the tracking operation.
IO(): Set Io_track_start = 1. Use the global I2C address
to simultaneously track down power supplies across
multiple LTC2970’s.
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OPERATIO
LTC2970-1 response: Each tracking enabled channel is soft
connected. The GPIO_CFG pin is released allowing it to be
pulled high. The LTC2970-1 waits tSETUP_TRACK to allow
GPIO_CFG to settle. For each tracking enabled channel,
the Chn_a_delay_track counter is decremented at a rate
of tDEC_TRACK. As soon as a channel’s tracking counter
reaches zero, the LTC2970-1 will begin stepping the value
of Chn_a_idac[7:0] by one count until the final value of
Chn_a_idac_track[7:0] is reached. The tracking enable bit
is then cleared for both channels (Chn_a_idac_track_en
= 0).
IO(): The I2C interface may then be used to set GPIO_1
and GPIO_0 low, disabling the power supplies.
Power Down Tracking Rules:
Power down tracking requests will be ignored until the
user has disabled the IDAC’s by setting Chn_a_idac_en =
0 for each tracking enabled channel.
Chn_a_idac_track_pol, Chn_a_idac_track_en, and ch0_
idac[7:0] updates will be ignored after IO(IO_track_start) is
asserted until tracking is complete and whenever tracking
range is configured; (GPIO_CFG high with either GPIO_0
or GPIO_1 asserted high).
Determine the target servo voltage, Chn_a_servo[14:0].
Update CHn_A_SERVO() with Chn_a_servo_en = 1, and
Chn_a_servo[14:0].
Update CHn_A_IDAC() with Chn_a_idac_servo_repeat =
1. This step may be skipped if Chn_a_idac_servo_repeat
was set high during the soft or hard connect procedure.
LTC2970 response: The LTC2970 will continuously increment, decrement or hold Chn_a_idac[7:0] in order
to match the measured value of (VINn_AP-VINn_AM) to
Chn_a_servo[14:0].
Whenever the CHn_A_SERVO() register is updated an internal flag is cleared indicating that a successful servo has
not been completed. This internal flag, Chn_a_servo_done,
initially causes the ADC to operate in an accelerated 12-bit
mode. Once the channel reaches the servo target, the ADC
switches back to 14-bit mode for two conversions before
asserting Chn_a_servo_done high.
In continuous voltage servo mode the Chn_a_servo_done
flags allow the initial servo target to be reached quickly.
During this time, ADC conversions for all non-servo channels are temporarily inhibited.
Rules:
12. Continuous Power Supply Voltage Servo
The continuous voltage servo feature allows the LTC2970
to servo an external power supply to a programmed
value. The voltage of the external supply is monitored
over Chn_A_ADC and compared to a target value stored
in Chn_a_servo. After each conversion, Chn_A_IDAC is
incremented by 1, decremented by 1, or held; whichever
brings or keeps the measured voltage closer to the targeted
servo value.
Procedure:
Follow procedure for hard connecting or soft connecting
the LTC2970 to power supply trim pin; when updating
CHn_A_IDAC(), Chn_a_idac_servo_repeat should be asserted high. The servo channel’s IDAC must be enabled
before Chn_A_servo_en can be set high.
The IDAC associated with the servo channel must be
enabled. If Chn_a_idac_en is low the servo enable bit
Chn_a_servo_en is always forced low.
The IDAC associated with the servo channel must be connected (Chn_a_idac_con = 1).
An IDAC fault may be generated during a continuous servo
operation. The LTC2970 will report the fault and continue
trying to servo that channel.
LTC2970-1 Only: There must be no pending tracking
commands. A pending tracking command will clear
Chn_a_servo_en.
LTC2970-1 Only: The tracking range must not be enabled;
(GPIO_CFG high with either GPIO_0 or GPIO_1 asserted
high). An enabled tracking range will clear Chn_a_servo_en
low.
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13. One Time Power Supply Voltage Servo
Procedure:
The one time voltage servo feature allows the LTC2970 to
servo an external power supply to a programmed value
and then stop updating the IDAC once the target value
has been reached.
Follow procedure outlined for “One Time Power Supply
Voltage Servo”.
Procedure:
Follow procedure for hard connecting or soft connecting
the LTC2970 to power supply trim pin; when updating
CHn_A_IDAC(), Chn_a_idac_servo_repeat should be deasserted low. The servo channel’s IDAC must be enabled
before Chn_a_servo_en may be set high.
Update CHn_A_IDAC() with Chn_a_idac_servo_repeat = 0.
This step may be skipped if Chn_a_idac_servo_repeat was
cleared low during the soft or hard connect procedure.
Update FAULT_EN() with Fault_en_chn_a_servo = 0. This
prevents the LTC2970 from reinitiating a servo after an
over-voltage or under-voltage fault.
Determine the target servo voltage, Chn_a_servo[14:0].
Update CHn_A_SERVO() register with Chn_a_servo_en
= 1, and Chn_a_servo[14:0].
LTC2970 response: The LTC2970 will increment, decrement
or hold Chn_a_idac[7:0] in order to match the measured
value of (VINn_AP-VINn_AM) to Chn_a_servo[14:0]. The
servo procedure will end when the internal Chn_a_servo_
done flag is set (see “Continuous Power Supply Voltage
Servo”). At this point the IDAC is either programmed to
the appropriate servo value or faulted.
Rules:
All “Continuous Power Supply Voltage Servo” rules
apply.
14. One Time Power Supply Voltage Servo with
Repeat On Fault
The LTC2970 one time voltage servo feature may be
modified to allow the LTC2970 to perform an additional
power supply servo operation after an under-voltage or
over-voltage fault is detected on the servo channel.
Update FAULT_EN() with Fault_en_chn_a_servo = 1.
Enable detection of the appropriate instantaneous faults
for all servo channels; see “Generating and Monitoring
Instantaneous Faults”.
LTC2970 response: Any time an instantaneous undervoltage or over-voltage fault is detected on the servo
channel (Fault_ov_a_chn or Fault_uv_a_chn), the internal
Chn_a_servo_done flag for that channel is cleared, and
the LTC2970 will perform a complete one time servo. This
allows the LTC2970 to precisely restore the power supply
to the target servo value, after it has drifted beyond a user
defined operating window.
Rules:
All “Continuous Power Supply Voltage Servo” rules
apply.
During a permanent under-voltage or over-voltage fault
the LTC2970 will continuously try to correct the faulted
channel, after each failed attempt all other channels that
need monitoring by the ADC will be serviced.
15. Configuring ADC to Monitor Input Channels and
Internal Temperature Sensor
The LTC2970 is able to perform ADC conversions on any
combination of seven different input channels. A channel
is converted if its associated ADC_MON() bit is set high.
Refer to Table 7 for details.
Procedure:
Update ADC_MON() with the control bit of each channel
that is to be monitored set high.
LTC2970 response: All enabled channels will be sequentially converted. The result of the most recent conversion
may be read from the ADC result register. Each time a
conversion is completed the new data bit associated with
the result register is asserted high. The new data bit is
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Table 7. LTC2970 ADC Conversion and Fault Limit Registers
INPUT CHANNEL
ADC_MON()
CONTROL BIT
ADC RESULT REGISTER
(2s COMPLEMENT)
OV FAULT REGISTER
(2s COMPLEMENT)
UV FAULT REGISTER
(2s COMPLEMENT)
TEMPERATURE
Adc_mon_temp
Temp_adc[14:0]
-
-
VIN1_BP-VIN1_BM
Adc_mon_b_ch1
Ch1_b_adc[14:0]
Ch1_b_ov[14:0]
Ch1_b_uv[14:0]
VIN1_AP-VIN1_AM
Adc_mon_a_ch1
Ch1_a_adc[14:0]
Ch1_a_ov[14:0]
Ch1_a_uv[14:0]
VIN0_BP-VIN0_BM
Adc_mon_b_ch0
Ch0_b_adc[14:0]
Ch0_b_ov[14:0]
Ch0_b_uv[14:0]
VIN0_AP-VIN0_AM
Adc_mon_a_ch0
Ch0_a_adc[14:0]
Ch0_a_ov[14:0]
Ch0_a_uv[14:0]
12VIN
Adc_mon_v12
V12_adc[14:0]
V12_ov[14:0]
V12_uv[14:0]
VDD
Adc_mon_vdd
Vdd_adc[14:0]
Vdd_ov[14:0]
Vdd_uv[14:0]
reset each time the result register is read. This provides a
simple mechanism for supervisory software to determine
if a new conversion has been completed since data was
last read.
Rules:
The LTC2970 assigns priority to ADC conversions of
CH1_A_ADC and CH0_A_ADC when these channels are
in their initial fast servo mode.
The IO() register control bit Io_i2c_adc_wen must be low
in order for ADC conversions to be performed.
16. Generating and Monitoring Instantaneous Faults
The LTC2970 supports fourteen different types of instantaneous faults. These faults together with the conditions
that trigger them are defined in Table 8. There are six
under-voltage faults, six over-voltage faults and two IDAC
limit faults. The FAULT() command may be used to read
the status of all instantaneous fault bits. The IO() command may be used to configure GPIO_0 and GPIO_1 to
view voltage limit and IDAC faults respectively. The state
of GPIO_0 and GPIO_1 may be read using IO().
LTC2970-1 Only: ADC conversions are suspended during
any pending tracking requests.
Table 8. LTC2970 Fault Reporting Bits and Conditions
CONDITION THAT GENERATES AN
INSTANTANEOUS FAULT
FAULT()
FAULT_EN()
FAULT_LA()
INSTANTANEOUS FAULT REPORTING ENABLE FOR LATCHED FAULT REPORTING LATCHED FAULT REPORTING
V12_adc[14:0] < V12_uv[14:0]
Fault_v12_uv
Fault_en_v12_uv
Fault_la_v12_uv
V12_adc[14:0] > V12_ov[14:0]
Fault_v12_ov
Fault_en_v12_ov
Fault_la_v12_ov
Vdd_adc[14:0] < Vdd_uv[14:0]
Fault_vdd_uv
Fault_en_vdd_uv
Fault_la_vdd_uv
Vdd_adc[14:0] > Vdd_ov[14:0]
Fault_vdd_ov
Fault_en_vdd_ov
Fault_la_vdd_ov
Ch1_b_adc[14:0] < Ch1_b_uv[14:0]
Fault_ch1_b_uv
Fault_en_ch1_b_uv
Fault_la_ch1_b_uv
Ch1_b_adc[14:0] > Ch1_b_ov[14:0]
Fault_ch1_b_ov
Fault_en_ch1_b_ov
Fault_la_ch1_b_ov
Idac_a_ch1[7:0] = 8’ff or 8’h00
Fault_ch1_a_idac
Fault_en_ch1_a_idac
Fault_la_ch1_a_idac
Ch1_a_adc[14:0] < Ch1_a_uv[14:0]
Fault_ch1_a_uv
Fault_en_ch1_a_uv
Fault_la_ch1_a_uv
Ch1_a_adc[14:0] > Ch1_a_ov[14:0]
Fault_ch1_a_ov
Fault_en_ch1_a_ov
Fault_la_ch1_a_ov
Ch0_b_adc[14:0] < Ch0_b_uv[14:0]
Fault_ch0_b_uv
Fault_en_ch0_b_uv
Fault_la_ch0_b_uv
Ch0_b_adc[14:0] > Ch0_b_ov[14:0]
Fault_ch0_b_ov
Fault_en_ch0_b_ov
Fault_la_ch0_b_ov
Idac_a_ch0[7:0] = 8’ff or 8’h00
Fault_ch0_a_idac
Fault_en_ch0_a_idac
Fault_la_ch0_a_idac
Ch0_a_adc[14:0] < Ch0_a_uv[14:0]
Fault_ch0_a_uv
Fault_en_ch0_a_uv
Fault_la_ch0_a_uv
Ch0_a_adc[14:0] > Ch0_a_ov[14:0]
Fault_ch0_a_ov
Fault_en_ch0_a_ov
Fault_la_ch0_a_ov
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Procedure:
Update the over-voltage limit register with the value above
which the ADC result should generate an over-voltage fault.
Instantaneous over-voltage faults are updated after each
ADC conversion. They are asserted high when the ADC
result is greater than the over-voltage limit. They are cleared
if the ADC result is less than or equal to the over-voltage
limit. Setting the over-voltage limit to 14’h3fff inhibits
instantaneous faults for the associated channel.
Update the under-voltage limit register with the value below
which the ADC result should generate an under-voltage
fault. Instantaneous under-voltage faults are updated
after each ADC conversion. They are asserted high when
the ADC result is less than the under-voltage limit. They
are cleared if the ADC result is greater than or equal to
the under-voltage limit. Setting the over-voltage limit to
14’h4000 inhibits instantaneous faults for the associated
channel.
Update ADC_MON() control bits to allow ADC conversions
on all channels that are to be monitored for over and under
voltage limits. Instantaneous IDAC faults are polled after
all ADC conversions are completed and set when the associated IDAC registers are at ‘h00 of ‘hff.
Read FAULT() to view the value of all instantaneous
faults.
The IO(Io_cfg_0) command may be used to configure
the GPIO_0 pin to output the internal Power_good flag.
Power_good is asserted high if there are no instantaneous
over-voltage or under-voltage faults. IO() may be used to
read the value of Power_good through io_gpio_0.
The IO(Io_cfg_1) command may be used to configure the
GPIO_1 pin to output the internal Idac_fault flag. Idac_fault
is asserted high if either IDAC value is faulted. IO() may be
used to read the value of Idac_fault through io_gpio_1.
Rules:
The over-voltage and under-voltage limits must be initialized; they do not have a default value.
All over-voltage limits, under-voltage limits and ADC results use 2’s complement notation with bit position [14]
of register [14:0] being used for the sign.
Instantaneous Ch0_a and Ch1_a faults may be used to
trigger a servo on fault event.
Over-voltage and under-voltage faults require that the
associated ADC_MON control bit be asserted high for
instantaneous fault detection to be updated.
17. Generating and Monitoring Latched Faults
The LTC2970 is able to selectively latch instantaneous faults
in the latched fault register FAULT_LA. Each instantaneous
fault has an associated latched fault bit in FAULT_LA and
a fault enable bit in FAULT_EN; (see Table 8) for details.
When an instantaneous fault enable bit is high, any event
that sets the instantaneous fault will simultaneously set
the latched fault. The latched fault will remain set even if
conditions permit the instantaneous fault to be cleared.
The latched faults are immediately cleared whenever the
associated fault enable bit is cleared. All latched faults are
also cleared when the latched fault register is read over
FAULT_LA().
The FAULT_INDEX() command may be read to determine
if any latched faults are asserted. Reading FAULT_INDEX()
does not clear latched faults. The ALERT output may also
be configured to view whether any latched faults are asserted.
Procedure:
Follow procedure for generating instantaneous faults.
Write FAULT_EN() to enable any combination of latched
faults.
Read FAULT_INDEX() to determine if any latched faults
are asserted without clearing latched faults.
Read FAULT_LA() to monitor all latched faults. Reading
FAULT_LA() will clear all latched faults. These will remain
clear until the next time the LTC2970 polls and sets an
associated instantaneous fault.
Setting IO(Io_alert_enb) low will cause ALERT to be asserted low whenever any one of the fourteen latched faults
is asserted high. The value of the ALERT pin may also be
read through IO(Alertb).
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Rules:
Rules:
See “Generating and Monitoring Instantaneous Faults”.
The power on reset configurations for GPIO_0 and GPIO_1
are output pins with a value equal to the complement of
the GPIO_CFG level.
18. General Purpose Input/Output Pins
The GPIO_0 and GPIO_1 may be used to: (1) monitor
instantaneous faults (see “Generating and Monitoring
Instantaneous faults”); (2) control switcher run/start pins
during tracking (see “Tracking Power Supplies Overview”);
or (3) provide general purpose input/output pins.
Procedure:
To program GPIO_n as an open drain output set Io_cfg_n
= 2’b10. The value written to lo_gpio_n will be output
over GPIO_n.
To program GPIO_n as an input set Io_cfg_n = 2’b11. The
value of GPIO_n may now be read through lo_gpio_n.
19. Advanced Development Features
The internal ADC may be disabled with the ADC result
registers accepting written I2C data. This feature allows
faults to be generated for diagnostic purposes, without
having to generate an actual overvoltage or undervoltage
event.
Procedure:
Set IO(Io_i2c_adc_wen) high to enable ADC result register
writes and disable internal ADC updates.
Rules:
Io_i2c_adc_wen must be clear for normal operation.
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Margining DC/DC Converters with External Feedback
Resistors
8V TO 15V
0.1μF
VIN
R50
Figure 1 shows a typical application circuit for margining
a power supply with an external feedback network. The
VIN0_AP and VIN0_AM differential inputs sense the load voltage directly, and differential inputs VIN0_BP and VIN0_BM
are connected across load current sense resistor R50. A
correction voltage is developed at the IOUT0 pin by sourcing
IDAC0’s current into resistor R40. R40 is Kelvin connected
to the point-of-load GND in order to isolate VIOUT0 from
ground bounce due to load current changes. VIOUT0 is
replicated at VOUT0 by an on-chip, unity-gain voltage buffer.
VOUT0 is then connected to the feedback node of the power
supply through resistor R30. The feedback node can be
isolated from the DAC’s correction voltage by placing the
VOUT0 pin in high-impedance mode. Since the GPIO_CFG
pin is pulled-up to VDD, the LTC2970’s GPIO_0 pin will
automatically hold the power supply’s RUN/SS pin low
after power-up until the I2C interface releases it.
VIN
IN
VDD
OUT
1/2 LTC2970
0.1μF
GPIO_CFG
I+
VIN0_BM
I–
VIN0_BP
DC/DC
CONVERTER
R30
R20
RUN/SS
FB
R10
GND SGND
ALERT
VOUT0
SCL
VIN0_AP
SDA
I2C BUS
+
LOAD VDC0
–
IOUT0
GPIO_0
R40
VIN0_AM
REF
GND ASEL0 ASEL1
0.1μF
29701 F01
Figure 1. Typical LTC2970 Application Circuit for
DC/DC Converters with External Feedback Resistors
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⎛ R20 ⎞
VDC0,NOM = VFB • ⎜ 1+
+ I • R20
⎝ R10 ⎟⎠ FB
4-Step Resistor Selection Procedure for DC/DC
Converters with External Feedback Resistors
The following 4-step procedure should be used to quickly
calculate the resistor values shown for the Typical Application Circuit shown in Figure 1.
R20
•
R30
(R40 • 236μA − VFB0 − 10mV )
VDC0,MIN ≤ VDC0,NOM −
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 desired output voltage of the DC/DC converter when the LTC2970’s VOUT0 pin is in a high impedance
state. VFB0 is the voltage at the converter’s feedback node
when the loop is in regulation, and IFB0 is the feedback
node’s input current.
R10 =
R20 • VFB0
VDC,NOM − IFB0 • R20 − VFB0
(1)
2. Solve for the maximum value of R30 that yields the
maximum required DC/DC converter output voltage
VDC0,max.
When VOUT0 is at 0V, the output of the DC/DC converter
is at its maximum voltage. Note that the 10mV term corresponds to the maximum offset voltage of the IDAC 1X
voltage buffer.
R30 ≤
R20 • ( VFB − 10mV )
VDC,MAX − VDC,NOM
(2)
3. Solve for the minimum value of R40 that’s needed
to yield the minimum required DC/DC converter output
voltage VDC0,MIN.
(4)
VDC0,MAX ≥ VDC0,NOM +
(5)
R20
• ( VFB0 − 10mV )
R30
The margining resolution is bounded by:
R20
• R40 • 276μA
volts/DAC LSB
VRES ≤ R30
256
(7)
Margining DC/DC Converters with a TRIM Pin
Figure 2 illustrates a typical application circuit for margining
the output voltage of a DC/DC converter with a TRIM Pin.
The LTC2970’s VOUT0 pin connects directly to the TRIM
pin through resistor R30 and the IOUT0 pin is terminated
at the converter's point-of-load ground throught R40.
Resistors R30 and R40 give this application circuit two
degrees of freedom so that the margin-up and margindown percentages can be specified independently.
Following power-up, the LTC2970's VOUT0 pin defaults to a
high-impedance state. If the soft-connect feature is used,
8V TO 15V
0.1μF
12VIN
VIN
VDD
VO+
1/2 LTC2970
The DC/DC converter output voltage will be a minimum
when IDAC0 is at its full-scale current. In order to guarantee
that R40 is large enough, assume that IDAC0’s full-scale
current is at the datasheet minimum of 236μA.
(6)
0.1μF
GPIO_CFG
R30
VOUT0
TRIM
DC/DC
CONVERTER
VIN0_AP
ALERT
SCL
I2C BUS
SDA
VSENSE+
+
R40 ≥
(
)
R30
+ V + 10mV
R20 FB
(3)
236μA
VDC,NOM − VDC,MIN •
4. Re-calculate the minimum, nominal, and maximum
DC/DC converter output voltages and the resulting margining resolution.
ON/OFF
LOAD VDC0
–
VSENSE–
VO–
IOUT0
GPIO_0
R40
VIN0_AM
REF
GND ASEL0 ASEL1
0.1μF
29701 F02
Figure 2. LTC2970 Application Circuit for
DC/DC Converters with a TRIM Pin
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the LTC2970 will automatically find the IDAC code that most
closely approximates the TRIM pin's open-circuit voltage
before enabling VOUT0. Note: The relationship between
VTRIM and the converter's output is typically non-inverting, so be sure to set the LTC2970's CH0_a_idac_pol bit
to 1 in order to allow the voltage servo feature to function
properly.
DC/DC converters with a TRIM pin are usually margined
high or low by connecting an external resistor between
the TRIM pin and either the VSENSE+ or VSENSE– pin. The
relationships between these resistors and the Δ% change
in the output voltage of the DC/DC converter are typically
expressed as:
RTRIM _ DOWN =
RTRIM • 50
− RTRIM
ΔDOWN %
(8)
RTRIM _UP =
⎡ RTRIM • VDC • (100 + ΔUP %) RT RIM • 50
⎤
− RTRIM ⎥
−
⎢
ΔUP %
2 • VREF • ΔUP %
⎣
⎦
(9)
Tracking with the LTC2970-1
A typical LTC2970-1 tracking application circuit is shown in
Figure 3 (the sequence of events for tracking are described
in sections 9 and 10 of the Operation section). The GPIO_0
and GPIO_1 pins are tied directly to their respective DC/DC
converter RUN/SS pins. Since GPIO_CFG is pulled-up to
VDD, the LTC2970-1 will automatically hold off the DC/DC
converters after power-up by asserting open drain outputs
GPIO_0 and GPIO_1 low. N-channel FETs Q10/11 and
diodes D10/11 form unidirectional range switches around
resistors R30A/31A while GPIO_CFG is high. These range
switches allow the LTC2970-1’s VOUT0 and VOUT1 pins to
drive the converter outputs all the way to/from ground
through resistors R30B/31B. When GPIO_CFG pulls low,
N-channel FETs Q10 and Q11 will turn off. R30A/31A
and R30B/31B then combine in series for normal margin
operation. The 100k/0.1μF low-pass filter in series with
the gates of Q10/11 minimizes charge injection into the
feedback nodes of the DC/DC converters when GPIO_CFG
pulls low.
8V TO 15V
where RTRIM is the resistance looking into the TRIM pin,
VREF is the TRIM pin's opern-circuit output voltage and
VDC is the DC/DC converter's nominal output voltage.
ΔUP% and ΔDOWN% denote the percentage change in the
converter's output voltage when margining up or down
respectively.
0.1μF
12VIN
VDD
10k
Q10, Q11: 2N7002
D10, D11: MMBD4448V
*SOME DETAILS OMITTED FOR CLARITY
0.1μF
GPIO_CFG
100k
GPIO_0
RUN/SS
D10
LTC2970-1
VIN
IN
DC/DC
CONVERTER
Q10
VOUT0
2-Step Resistor Selection Procedure for DC/DC
Converters with a TRIM Pin
R30B
ALERT
I2C BUS
The following two-step procedure should be used to
calculate values for resistors R30 and R40 shown in
Figure 2.
R10
SCL
IOUT0
SDA
0.1μF
RUN/SS
D11
Q11
R31B
R11
(10)
GND
VDC1
OUT
FB
R31A
R21
IOUT1
R41
29701 F03
2. Solve for R40:
⎛
ΔUP % ⎞ VREF
•
R40 ≥ ⎜ 1 +
ΔDOWN % ⎟⎠ 236μ A
⎝
VIN
IN
DC/DC
CONVERTER
VOUT1
⎛ 50 − ΔDOWN % ⎞
R30 ≤ RTRIM • ⎜
⎝ ΔDOWN % ⎟⎠
R20
R40
GPIO_1
1. Solve for R30:
VDC0
OUT
FB
R30A
Figure 3. LTC2970-1 Tracking Application Circuit
(11)
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7-Step Procedure for Calculating Tracking Application
Circuit Resistor Values, Counter Delay Values, and
Terminal IDAC Codes
The following 7-step procedure should be used to calculate
the resistor values, tracking counter delays, and terminal
IDAC codes for the Tracking Application Circuit shown in
Figure 3.
1. Assume a value for R20 and solve for R21.
VDCn,NOM is the output voltage of the DC/DC converter when
the LTC2970’s VOUTn pin is in a high impedance state.
VDC1,NOM
R21= R20 •
(12)
VDC0,NOM
Due to the forward drop of diodes D10 and D11 (0.8V
max), the minimum value for R40 = R41 from expression
(14) may result in small or even negative values of R30
and R31 in Step 4. If this is the case, assume a minimum
allowable value for R3nB, and use the following expression
to calculate the minimum value R40 = R41:
R40 = R41≥
(15)
⎛ R3nB R3nB ⎞
VFBn • ⎜ 1+
+
+ 0.8 V + 10mV
⎝
R1n
R2n ⎟⎠
236μA
Note: Use the channel whose parameters yield the maximum value for R40 = R41.
4. Solve for R30B and R31B.
2. Solve for R10 and R11.
R1n =
R2n
(13)
⎛ VDCn,NOM ⎞
− 1⎟
⎜⎝ V
⎠
FBn
Solve for the upper limits of R30B and R31B and then
determine which resistor value constrains the maximum
value of the other resistor using Equation 17.
R3nB ≤
(R4n • 236μA − VFBn − 0.8V − 10mV )
3. Solve for R40 and R41.
For simplicity, this procedure assumes that R40 = R41.
VDCn,MAX and VDCn,MIN are the maximum and minimum
converter output margin voltages, respectively.
The value of R40 = R41 is constrained by:
R40 = R41≥
(
(
)
)
R30B R31B
=
R20 R21
(16)
(17)
5. Solve for R30A and R31A.
(14)
⎛ VDCn,NOM − VDCn,MIN
⎞
+ 1⎟ + 10mV
VFBn • ⎜
⎜⎝ VDCn,MAX − VDCn,NOM
⎟⎠
236μA
1 ⎞
⎛ 1
VFBn • ⎜
+
⎝ R1n R2n ⎟⎠
R30A and R31A are constrained by:
R3nA ≤
(18)
R2n
⎛ R2n ⎞ ⎛ VDCn,MAX − VDCn,NOM ⎞
⎜⎝ 1+ R1n ⎟⎠ • ⎜
⎟
VDCn,NOM
⎝
⎠
− R3nB
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6. Solve for Channel 1’s tracking counter delay relative to
Channel 0, CH1_A_DELAY_TRACK().
CH1_ A _ DELAY _ TRACK() =
R31B
VDC1,NOM′ − VDC0,NOM′ •
R21 (counts)
1μA / count • R41
(
)
(19)
From Equation 2:
R30 ≤
Note: VDCn,NOMʹ is based on the final values of R2n and
R1n. If the result for CH1_A_DELAY_TRACK() is less than
0, apply the unsigned result to the CH0_A_DELAY_TRACK()
register.
7. Solve for the IDAC0 and IDAC1 terminal tracking codes,
Chn_a_idac_track[7:0].
Chn _ a _ idac _ track[7 : 0] =
VFBn
255 −
(LSB’s)
1μA / LSB • R4n
2. Solve for the value of R30 that yields the maximum
required DC/DC converter output voltage VDC0,MAX
(20)
Note: This formula assumes that the Chn_a_idac_pol bit
is set to 0.
Margining Application Circuit Design Example
R20 • ( VFB − 10mV )
=
VDC,MAX − VDC,NOM
10.0kΩ • ( 0.8 V − 10mV )
= 7, 861Ω
3.63V − 2.625V
Let R30 = 7.68kΩ.
3. Solve for the value of R40 that’s needed to yield the
minimum required DC/DC converter output voltage
VDC0,MIN.
From Equation 3:
R40 ≥
+V
( VDC,NOM − VDC,MIN ) • RR30
20 FB
=
236μA
.96kΩ
+ 0.8 V
(2.625V − 1.62V ) • 710
kΩ
= 6, 780Ω
236μA
Consider the LTC2970 application circuit shown in Figure
1. Channel 0 is a DC/DC converter whose output needs
to be varied between 3.63V and 1.62V. VFB0 = 0.8V and
assume that IFB0 = 0A.
Let R40 = 6.81kΩ.
1. Assume values for feedback resistor R20 and the
nominal DC/DC converter output voltage VDC0,NOM, and
solve for R10.
From Equations 4, 5, and 6:
Let VDC0,NOM = 2.625V (the average of 3.63V and 1.62V)
and assume that R20 = 10kΩ. From Equation 1:
R10 =
R20 • VFB0
=
VDC,NOM − IFB0 • R20 − VFB0
10kΩ • 0.8 V
= 4, 384Ω
2.625V − 0.8 V
Let R10 = 4.37kΩ (the nearest E192 series resistor
value).
4. Re-calculate the minimum, nominal, and maximum
DC/DC converter output voltages and the resulting margining resolution.
⎛ R20 ⎞
VDC0,NOM = VFB • ⎜ 1+
+ I • R20 =
⎝ R10 ⎟⎠ FB
10kΩ ⎞
⎛
0.8 V • ⎜ 1+
= 2.631V
⎝ 4.37kΩ ⎟⎠
VDC0,MIN < VDC0,NOM −
R20
• ( 236μA • R40 − VFB0 )
R30
10kΩ
•
7.68kΩ
(236μA • 6.81kΩ − 0.8V − 10mV ) = 1.59V
→ VDC0,MIN < 2.631V −
29701fc
31
LTC2970/LTC2970-1
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APPLICATIO S I FOR ATIO
VDC0,MAX > VDC0,NOM +
R20
• ( VFB0 − 10mV )
R30
10kΩ
•
7.68kΩ
(0.8V − 10mV ) = 3.660V
→ VDC0,MAX > 2.631V +
From Equation 7, the margining resolution will be less
than:
R20
• R40 • 276μA
R
30
VRES <
=
256
10kΩ
• 6.65kΩ • 276μA
7.68kΩ
= 9.33mV/LSB
256
Margining DC/DC Converter with TRIM Pin Design
Example
The output voltage of the DC/DC converter in Figure 2 needs
to be margined ±10% about its nominal value. Assume
that RTRIM = 10.22kΩ and VREF = 1.225V.
Tracking Application Circuit Design Example
Consider the LTC2970-1 application circuit shown in Figure
3. Channel 0 is a 1.8V DC/DC converter while channel 1
is a 2.5V switching power supply. Both converters have
a feedback node voltage of 0.8V and need to track on and
off coincidentally. In addition, a margin range of +5% and
–10% is required for each supply.
1. Assume a value for R20 and solve for R21.
Let R20 = 5,970Ω. From Equation 12:
VDC1,NOM
R21= R20 •
VDC0,NOM
= 5, 970Ω •
2.5V
= 8, 292Ω
1.8 V
Let R21 = 8,250Ω (the nearest E192 Series resistor
value).
2. Solve for R10 and R11.
From Equation 13:
R10 =
R20
=
⎛ VDC0,NOM ⎞
− 1⎟
⎜⎝ V
⎠
FB0
5, 970Ω
= 4, 776Ω
⎛ 1.8 V ⎞
⎜⎝ 0.8 V − 1⎟⎠
1. Solve for R30 using Equation 10:
⎛ 50 − ΔDOWN % ⎞
R30 ≤ RTRIM • ⎜
% ⎟⎠
⎝ Δ
DOWN
⎛ 50 − 1 0 ⎞
= 10 . 22kΩ • ⎜
= 40, 880Ω
⎝ 10 ⎟⎠
R11=
R21
⎛ VDC1,NOM ⎞
− 1⎟
⎜⎝ V
⎠
=
FB1
8, 250Ω
= 3, 882Ω
⎛ 2.5V ⎞
⎜⎝ 0.8 V − 1⎟⎠
Let R10 = 4,750Ω and R11 = 3,880Ω.
3. Solve for R40 and R41.
Let R30 = 39.2kΩ.
2. Solve for R40 using Equations 11:
⎛
ΔUP % ⎞ VREF
•
R40 ≥ ⎜ 1 +
ΔDOWN % ⎟⎠ 236μ A
⎝
⎛ 10 ⎞ 1 . 225V
= ⎜ 1+ ⎟ •
= 10, 381Ω
⎝ 10 ⎠ 236μ A
Let R40 = 10.5kΩ.
Assume that R40 = R41.
R40 = R41≥
(
(
)
)
⎛ VDCn,NOM − VDCn,MIN
⎞
VFBn • ⎜
+ 1⎟ + 10mV
⎜⎝ VDCn,MAX − VDCn,NOM
⎟⎠
=
236μA
⎛ (1− 0.9) ⎞
0.8 V • ⎜
+ 1 + 10mV
⎝ (1.05 − 1) ⎟⎠
= 10, 212Ω
236μA
Let R40 = R41 = 10.5kΩ
29701fc
32
LTC2970/LTC2970-1
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APPLICATIO S I FOR ATIO
4. Solve for R30B and R31B.
(R40 • 236μA − VFB0 − 0.8V − 10mV ) =
R30B ≤
1 ⎞
⎛ 1
+
VFB0 • ⎜
⎝ R10 R20 ⎟⎠
(10.5kΩ • 236μA − 0.8 V − 0.8 V − 10mV)
= 2, 870Ω
1
1 ⎞
⎛
+
0.8 V • ⎜
⎝ 4, 750Ω 5, 970Ω ⎟⎠
R31B ≤
(R41• 236μA − VFB1 − 0.8V − 10mV ) =
1 ⎞
⎛ 1
VFB1 • ⎜
+
⎝ R11 R21⎟⎠
(10.5kΩ • 236μA − 0.8 V − 0.8 V − 10mV)
= 2, 863Ω
1
1 ⎞
⎛
+
0.8 V • ⎜
⎝ 3, 880Ω 8, 250Ω ⎟⎠
For coincident tracking to occur Equation 17 also must
be satisfied:
R30B R31B
=
R20 R21
→ R30B =
→ R31B =
R21
⎛ R21⎞ ⎛ VDC1,MAX − VDC1,NOM ⎞
⎜⎝ 1+ R11⎟⎠ • ⎜
⎟
VDC1,NOM
⎝
⎠
− R31B =
8, 250Ω
− 2, 890Ω = 49, 888Ω
⎛ 8, 250Ω ⎞ ⎛ 1.05 − 1⎞
⎜⎝ 1+ 3, 880Ω ⎟⎠ • ⎜⎝ 1 ⎟⎠
Let R30A = 49.9kΩ and R31A = 48.7kΩ.
6. Solve for Channel 1’s tracking counter delay relative to
Channel 0, CH1_A_DELAY_TRACK().
First, recalculate the values of VDCn,NOM based on the final
values of R1n and R2n:
⎛ R20 ⎞
+ I • R20 =
VDC0,NOM′ = VFB • ⎜ 1+
⎝ R10 ⎟⎠ FB
⎛ 5, 970Ω ⎞
+ 0 = 1.805V
0.8 V • ⎜ 1+
⎝ 4, 750Ω ⎟⎠
⎛ 8, 250Ω ⎞
VDC1,NOM′ = 0.8 V • ⎜ 1+
+ 0 = 2.501V
⎝ 3, 880Ω ⎟⎠
R31B
2, 863Ω
• R20 =
• 5, 970Ω = 2, 078Ω
R21
8, 250Ω
R30B
2, 870Ω
• R21=
• 8, 250Ω = 3, 957Ω
R20
5, 970Ω
Let R30B = 2,100Ω and R31B = 2,890Ω.
5. Solve for R30A and R31A.
Referring to Equation 18:
R30 A ≤
R31A ≤
R20
− R30B =
⎛ R20 ⎞ ⎛ VDC0,MAX − VDC0,NOM ⎞
⎜⎝ 1+ R10 ⎟⎠ • ⎜
⎟
VDC0,NOM
⎝
⎠
5, 970Ω
− 2,100Ω = 50, 806Ω
⎛ 5, 970Ω ⎞ ⎛ 1.05 − 1⎞
⎜⎝ 1+ 4, 750Ω ⎟⎠ • ⎜⎝ 1 ⎟⎠
Next, apply Equation 19:
CH1_ A _ DELAY _ TRACK() =
R31B
VDC1,NOM′ − VDC0,NOM′ •
R21 =
1μA / count • R41
Ω
(2.501V − 1.805V ) • 82,,890
250Ω
= 23 counts
1μA / count • 10.5kΩ
(
)
7. Solve for the IDAC0 and IDAC1 terminal tracking codes,
Chn_a_idac_track[7:0].
Ch0 _ a _ idac[7 : 0] = Ch1_ a _ idac[7 : 0] =
0.8 V
255 −
= 179
1μA / LSB • 10.5kΩ
29701fc
33
LTC2970/LTC2970-1
U
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APPLICATIO S I FOR ATIO
drop across resistor RSENSE. Since the VDD pin voltage
is monitored by the LTC2970, its tolerance can be accounted for when calculating the point of load voltage.
Transistor Q1 allows the IOUT0 pin to force current into
the converter’s feedback node without forward biasing
the LTC2970’s IOUT0 body diode. Note that IOUT0’s output
current defaults to 128μA after the LTC2970 comes out
of power-on reset.
2.7
2.4
VDC1
2.1
VOLTS
1.8
VDC0
1.5
1.2
0.9
0.6
0.3
0
29701 F04
5ms/DIV
15-Bit Programmable Power Supply Application
Circuit
Figure 4. Tracking Design Example DC/DC
Converter Output Waveforms
Figure 4 shows the DC/DC converter output voltages for
this design example tracking-up and tracking-down.
Temperature Sensor Conversion
The LTC2970's internal temperature sensor output is
proportional to absolute temperature (PTAT). In order to
convert the ADC reading to degress Celsius, apply the
following formula:
result (°C) =
ADC_temp_sensor_reading
− 273.15
4
(21)
Negative Power Supply Application Circuit
Figure 5 shows the LTC2970 controlling a negative power
supply. The R30/R40 resistor divider translates the point
of load voltage to the LTC2970’s VIN0_A inputs while the
VIN0_B inputs monitor the converter’s input current I • R
Figure 6 illustrates how both servo channels of the LTC2970
can be configured to adjust a single DC/DC converter over
a 15-bit dynamic range. R30 and R31 are sized to force
1 bit of overlap between the coarse (channel 0) and fine
(channel 1) servo loops. One coarse servo iteration should
be performed first on channel 0 with IDAC1 programmed
to mid-scale, and then channel 1 can be programmed to
servo to the desired voltage.
Programmable Reference Application Circuit
Figure 7 shows a LTC2970 configured as a programmable reference that can span a 0V to 3.5V range with
a resolution of 100μV and an absolute accuracy of less
than ±0.5%. The two IDAC’s are paralleled by terminating
IDAC1’s output resistor in the VOUT0 output and taking the
output of the composite DAC from VOUT1. IDAC0 should
servo once with IDAC1 set to mid-scale, and then IDAC1
can servo once, continuously, or trigger on drift to the
desired target voltage.
8V TO 15V
8V TO 15V
0.1μF
0.1μF
R20
0.1μF
12VIN
VDD
12VIN
VIN
VIN0_AP
IN
OUT
R10
R30
RUN/SS FB
0.1μF
29701 F05
R31 ≥ R30 • 128
R41 = R40
LOAD
( )
(
IOUT0
R41
SCL
I2C BUS
SDA
GPIO_0
R40
VIN0_AM
GND SGND
ALERT
IOUT1
LOAD
R10
GND ASEL0 ASEL1
VEE
VIN0_AP
VIN1_AP
REF
R20
R10
VOUT0
R31
R20
OUT
FB
DC/DC
CONVERTER
SDA
VIN0_BM
IOUT0
VIN
I2C BUS
SCL
Q1
TP0610K
DC/DC
CONVERTER
GPIO_CFG
VOUT1
ALERT
RSENSE
0.1μF
LTC2970
CLOAD
1/2 LTC2970
VIN0_BP
GND
VDD
+
VIN0_AM
REF
VIN1_AM
GND ASEL0 ASEL1
0.1μF
)
VOUT = VDD – 1 + R30 • VIN0_AP – VIN0_AM
R40
29701 F06
Figure 5. Negative Power Supply Application Circuit
Figure 6. Programmable Power Supply Application Circuit
29701fc
34
LTC2970/LTC2970-1
U
PACKAGE DESCRIPTIO
UFD Package
24-Lead Plastic QFN (4mm × 5mm)
(Reference LTC DWG # 05-08-1696)
2.65 ± 0.10
(2 SIDES)
R = 0.115
TYP
23 24
0.75 ± 0.05
4.00 ± 0.10
(2 SIDES)
PIN 1 NOTCH
R = 0.30 TYP
0.70 ±0.05
0.40 ± 0.05
PIN 1
TOP MARK
(NOTE 6)
4.50 ± 0.05
1
3.10 ± 0.05
2
2.65 ± 0.05
(2 SIDES)
5.00 ± 0.10
(2 SIDES)
0.25 ±0.05
0.50 BSC
3.65 ± 0.05
(2 SIDES)
4.10 ± 0.05
5.50 ± 0.05
3.65 ± 0.10
(2 SIDES)
(UFD24) QFN 0505
0.200 REF
PACKAGE OUTLINE
0.00 – 0.05
0.25 ± 0.05
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
NOTE:
1. DRAWING PROPOSED TO BE MADE A JEDEC PACKAGE OUTLINE MO-220 VARIATION (WXXX-X).
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION
ON THE TOP AND BOTTOM OF PACKAGE
U
TYPICAL APPLICATIO
8V TO 15V
0.1μF
12VIN
VDD
LTC2970
0.1μF
VIN1_AP
VIN1_AM
VIN0_AP
VIN0_AM
VOUT1
I2C BUS
SCL
SDA
IOUT1
22μF
+
VOUT
–
ALERT
100Ω
VOUT0
10Ω
IOUT0
12.7k
REF
GND ASEL0 ASEL1
0.1μF
29701 F07
Figure 7. Programmable Reference Application Circuit
29701fc
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.
35
LTC2970/LTC2970-1
U
TYPICAL APPLICATIO
8V TO 15V
10
R50
VIN
IN
0.1μF
12VIN
VDD
OUT
9
10k
4
I+
3
I–
DC/DC
CONVERTER 0
11
1
R30
GPIO_CFG
VIN0_BM
0.1μF
20
VIN0_BP
VOUT0
VIN0_AP
R20
RUN/SS
FB
LOAD
R10
14
IOUT0
R40
PGND SGND
2
VIN0_AM
ALERT
SCL
16
SDA
GPIO_0
17
18
19
I2C BUS
SMBUS
COMPATIBLE
(
)
LTC2970
R51
VIN
IN
OUT
8
I+
7
I–
12
DC/DC
CONVERTER 1
5
R31
VIN1_BM
VIN1_BP
VOUT1
VIN1_AP
R21
RUN/SS
FB
LOAD
R11
PGND SGND
13
IOUT1
R41
6
VIN1_AM
REF
23
0.1μF
15
RGND
GPIO_1
24
GND ASEL0 ASEL1
25
22
21
29701 TA01
Figure 8. Typical LTC2970 Application Circuit for
DC/DC Converters with External Feedback Resistors
RELATED PARTS
PART NUMBER
DESCRIPTION
COMMENTS
LTC2920-1/LTC2920-2
Single/Dual Power Supply Margining Controllers
Symmetric/Asymmetric High and Low Voltage Margining
LTC2921/LTC2922
Power Supply Trackers with Input Monitors
3 (LTC2921) or 5 (LTC2922) Remote Sense Switches
LTC2923
Power Supply Tracking Controller
Up to 3 Supplies
LTC2924
Quad Power Supply Sequencer
Voltage Monitoring and Sequence Error Detection and Reporting
LTC2925
Multiple Power Supply Tracking Controller
Power Good Timer, Remote Sense Switch
LTC2926
MOSFET Controller Power Supply Tracker
Up to 3 Modules
LTC2927
Single Power Supply Tracker
Point of Load Applications
29701fc
36 Linear Technology Corporation
0308 REV C • PRINTED IN USA
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(408) 432-1900 ● FAX: (408) 434-0507
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