LTC2923 - Power Supply Tracking Controller

LTC2923
Power Supply
Tracking Controller
Features
Description
Flexible Power Supply Tracking
n Tracks Both Up and Down
n Power Supply Sequencing
n Supply Stability is Not Affected
n Controls Two Supplies Without Series FETs
n Controls a Third Supply With a Series FET
n Adjustable Ramp Rates
n Electronic Circuit Breaker
n Available in 10-Lead MS and 12-Lead
(4mm × 3mm) DFN Packages
The LTC®2923 provides a simple solution to power supply
tracking and sequencing requirements. By selecting a few
resistors, the supplies can be configured to ramp-up and
ramp-down together or with voltage offsets, time delays
or different ramp rates.
n
By introducing currents into the feedback nodes of two
independent switching regulators, the LTC2923 causes
their outputs to track without inserting any pass element
losses. Because the currents are controlled in an openloop manner, the LTC2923 does not affect the transient
response or stability of the supplies. Furthermore, it
presents a high impedance when power-up is complete,
effectively removing it from the DC/DC circuit.
Applications
VCORE and VI/O Supply Tracking
Microprocessor, DSP and FPGA Supplies
nServers
n Communication Systems
n
n
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Patents Pending.
For systems that require a third supply, one supply can
be controlled with a series FET. This optional series FET
can also control a supply that does not allow direct access to its feedback resistors (e.g., a power module) or
a supply whose output cannot be forced to ground (e.g.,
a 3-terminal linear regulator). When the FET is used, an
electronic circuit breaker provides protection from shortcircuit conditions.
Typical Application
Q1
VIN
3.3V
3.3V
3.3V
2.5V
1.8V
1V/DIV
10nF
VIN
138k
VCC
GATE
ON
100k
RAMP
FB1
IN
DC/DC
FB = 1.235V
35.7k
STATUS
2923 TA02
TRACK1
SDO
TRACK2
FB2
887k
16.5k
VIN
16.5k
412k
1ms/DIV
1.8V
LTC2923
RAMPBUF
13k
OUT
IN
DC/DC
FB = 0.8V
3.3V
2.5V
1.8V
OUT
1V/DIV
2.5V
GND
412k
887k
2923 TA01
For more information www.linear.com/LTC2923
1ms/DIV
2923 TA02b
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1
LTC2923
Absolute Maximum Ratings (Note 1)
Supply Voltage (VCC) ................................. –0.3V to 10V
Input Voltages
ON.......................................................... –0.3V to 10V
TRACK1, TRACK2.........................–0.3V to VCC + 0.3V
RAMP..............................................–0.3V to VCC + 1V
Output Voltages
FB1, FB2, SDO, STATUS.......................... –0.3V to 10V
RAMPBUF.....................................–0.3V to VCC + 0.3V
GATE (Note 2).......................................–0.3V to 11.5V
Average Current
TRACK1, TRACK2.................................................5mA
FB1, FB2................................................................5mA
RAMPBUF.............................................................5mA
Operating Temperature Range
LTC2923C................................................. 0°C to 70°C
LTC2923I..............................................–40°C to 85°C
Storage Temperature Range................... –65°C to 150°C
Lead Temperature (Soldering, 10 sec)
MS Package....................................................... 300°C
PACKAGE/ORDER INFORMATION
TOP VIEW
VCC
1
12 RAMP
ON
2
11 GATE
TRACK1
3
TOP VIEW
VCC
ON
TRACK1
TRACK2
RAMPBUF
1
2
3
4
5
10
9
8
7
6
RAMP
GATE
FB1
FB2
GND
13
10 STATUS
TRACK2
4
9
SDO
RAMPBUF
5
8
FB1
GND
6
7
FB2
MS PACKAGE
10-LEAD PLASTIC MSOP
DE12 PACKAGE
12-LEAD (4mm × 3mm) PLASTIC DFN
TJMAX = 125°C, θJA = 120°C/W
TJMAX = 125°C, θJA = 43°C/W
EXPOSED PAD (PIN 13)
(PCB GND CONNECTION OPTIONAL)
Order Information
http://www.linear.com/product/LTC2923#orderinfo
TUBE
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2923CMS#PBF
LTC2923CMS#TRPBF
LTAED
10-Lead Plastic MSOP
0°C to 70°C
LTC2923IMS#PBF
LTC2923IMS#TRPBF
LTAEE
10-Lead Plastic MSOP
–40°C to 85°C
LTC2923CDE#PBF
LTC2923CDE#TRPBF
2923
12-Lead Plastic DFN
0°C to 70°C
LTC2923IDE#PBF
LTC2923IDE#TRPBF
2923
12-Lead 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/. Some packages are available in 500 unit reels through
designated sales channels with #TRMPBF suffix.
2
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LTC2923
Electrical
Characteristics
The
l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. 2.9V < VCC < 5.5V unless otherwise noted (Note 3).
SYMBOL
PARAMETER
CONDITIONS
MIN
VCC
Input Supply Range
ICC
Input Supply Current
IFBx = 0, ITRACKx = 0
IFBx = –1mA, ITRACKx = –1mA,
IRAMPBUF = –2mA
l
l
VCC(UVL)
Input Supply Undervoltage Lockout
VCC Rising
TYP
UNITS
5.5
V
5
1.3
7
3
10
mA
mA
l
2.2
2.5
2.7
V
l
2.9
MAX
∆VCC(UVLHYST) Input Supply Undervoltage Lockout Hysteresis
25
mV
∆VGATE
External N-Channel Gate Drive (VGATE – VCC)
IGATE = –1µA
l
5
5.5
6
IGATE
GATE Pin Current
Gate On, VGATE = 0V, No Faults
Gate Off, VGATE = 5V, No Faults
Gate Off, VGATE = 5V,
Short-Circuit Fault
l
l
l
–7
7
5
–10
10
20
–13
13
50
VON(TH)
ON Pin Threshold Voltage
VON Rising
l
1.212
1.230
1.248
∆VON(HYST)
VON(FC)
V
µA
µA
mA
V
ON Pin Hysteresis
l
30
75
150
mV
ON Pin Fault Clear Threshold Voltage
l
0.3
0.4
0.5
V
0
±100
nA
160
200
240
mV
ION
ON Pin Input Current
∆VDS(TH)
FET Drain-Source Overcurrent Voltage Threshold
(VCC – VRAMP)
VON = 1.2V, VCC = 5.5V
IRAMP
RAMP Pin Input Current
VRAMPBUF(OL) RAMPBUF Low Voltage
VRAMPBUF(OH) RAMPBUF High Voltage (VCC – VRAMPBUF)
l
l
0V < RAMP < VCC, VCC = 5.5V
l
0
±1
µA
IRAMPBUF = 2mA
l
90
150
mV
IRAMPBUF = –2mA
l
100
200
mV
0
30
mV
0
0
±5
±5
%
%
0.8
0.8
0.824
0.824
V
V
±1
±100
nA
VOS
Ramp Buffer Offset (VRAMPBUF – VRAMP)
VRAMPBUF = VCC/2, IRAMPBUF = 0A
IERROR(%)
IFBx to ITRACKx Current Mismatch
IERROR(%) = (IFBx – ITRACKx)/ITRACKx
ITRACKx = –10µA
ITRACKx = –1mA
l
l
VTRACKx
TRACK Pin Voltage
ITRACKx = –10µA
ITRACKx = –1mA
l
l
IFB(LEAK)
IFB Leakage Current
VFB = 1.5V, VCC = 5.5V
l
VFB(CLAMP)
VFB Clamp Voltage
1µA < IFB < 1mA
l
1.7
2
V
VSDO(OL)
SDO Output Low Voltage
ISDO = 3mA
l
0.2
0.4
V
VSTATUS(OL)
STATUS Output Low Voltage
ISTATUS = 3mA
l
0.2
0.4
V
tPSC
Short-Circuit Propagation Delay VDS High
to GATE Low
VDS = VCC, VCC = 2.9V
10
20
µs
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.
–30
0.776
0.776
1.5
Note 2: The GATE pin is internally limited to a minimum of 11.5V. Driving
this pin to voltages beyond the clamp may damage the part.
Note 3: All currents into the device pins are positive; all currents out of
device pins are negative. All voltages are referenced to ground unless
otherwise specified.
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3
LTC2923
Typical Performance Characteristics
Specifications are at TA = 25°C unless otherwise noted.
VGATE vs VCC
VGATE vs IGATE
12
IGATE vs VCC Fast Pull-Down
15
30
VCC = 5.5V
11
IGATE (mA)
20
VGATE (V)
VGATE (V)
10
10
VGATE = 5V
25
VCC = 2.9V
5
15
10
9
5
8
2
3
4
VCC (V)
5
0
6
5
0
10
IGATE (µA)
2923 G01
ICC (mA)
IGATE (mA)
25
VCC = 2.9V
15
10
2
3
VCC (V)
4
5
6
ICC vs VCC
8.0
ITRACKx = IFBx = 0mA
IRAMPBUF = 0mA
1.4
7.9
1.3
7.8
ICC (mA)
VCC = 5.5V
20
1
2923 G03
ICC vs VCC
1.5
40
30
0
2923 G02
IGATE Fast Pull-Down
vs Temperature
35
0
15
1.2
1.1
ITRACKx = IFBx = –1mA
IRAMPBUF = –2mA
7.7
7.6
5
0
–50
–25
0
50
25
TEMPERATURE (°C)
75
100
3
3.5
4
4.5
5
5.5
VCC (V)
2923 G04
4
1.0
2.5
2923 G05
7.5
2.5
3
3.5
4.5
4
VCC (V)
5
5.5
2923 G06
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LTC2923
Typical Performance Characteristics
Specifications are at TA = 25°C unless otherwise noted.
VTRACKx vs Temperature
VRAMPBUF(OL) vs Temperature
VCC = 5.5V
ITRACKx = 10µA
VCC = 5.5V
ITRACKx = 1mA
0.800
VRAMPBUF(OL) (mV)
VTRACKx (V)
0.805
0.795
0.790
VCC = 2.9V
ITRACKx = 10µA
0.785
–50
–25
VCC = 2.9V
ITRACKx = 1mA
0
25
50
TEMPERATURE (°C)
75
120
130
110
120
100
VCC = 2.9V
90
VCC = 5.5V
80
70
60
–50
100
VRAMPBUF(OH) vs Temperature
110
VCC = 2.9V
100
90
VCC = 5.5V
80
70
–25
0
25
50
TEMPERATURE (°C)
75
2923 G07
1.0
VRAMPBUF(OH) (mV)
0.810
60
–50
100
Tracking Cell Error vs ITRACKx
5
VTRACKx = 0V
ERROR =
15
ISDO = 5mA
ERROR (%)
13
12
11
10
0.2
0
4
14
ITRACKx (mA)
VSDO(OL) (V)
0.8
1
2
3
VCC (V)
VTRACKx
I
• FBx – 1
0.8V
ITRACKx
3
2
1
9
ISDO = 10µA
0
100
75
2923 G09
ITRACKx vs VCC
16
0.2
50
25
0
TEMPERATURE (°C)
2923 G08
VSDO(OL) vs VCC
0.6
–25
4
5
2923 G11
8
3
3.5
4
4.5
VCC (V)
5
5.5
2923 G10
0
0
1
3
2
ITRACKx (mA)
4
5
2923 G12
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5
LTC2923
Pin Functions
MS/DE Packages
VCC (Pin 1): Positive Supply Input Pin. The operating supply input range is 2.9V to 5.5V. An undervoltage lockout
circuit resets the part when the supply is below 2.5V. VCC
should be bypassed to GND with a 0.1µF capacitor.
ON (Pin 2): On Control Input. The ON pin has a threshold
of 1.23V with 75mV of hysteresis. An active high will cause
10µA to flow from the GATE pin, ramping up the supplies.
An active low pulls 10µA from the GATE pin, ramping the
supplies down. Pulling the ON pin below 0.4V resets the
electronic circuit breaker in the LTC2923. If a resistive
divider connected to VCC drives the ON pin, the supplies
will automatically start up when VCC is fully powered.
TRACK1, TRACK2 (Pins 3, 4): Tracking Control Input. A
resistive voltage divider between RAMPBUF and TRACKx
determines the tracking profile of a slave supply (see Applications Information). TRACKx pulls up to 0.8V and the
current supplied at TRACKx is mirrored at FBx. TRACKx
is capable of supplying at least 1mA when VCC = 2.9V.
Because a TRACKx pin is capable of supplying up to 30mA
under short-circuit conditions, avoid connecting TRACKx
to GND for extended periods. Limit the capacitance at
each TRACKx pin to less than 25pF. Float the TRACKx
pins if unused.
RAMPBUF (Pin 5): Ramp Buffer Output. Provides a low
impedance buffered version of the signal on the RAMP
pin. This buffered output drives the resistive dividers that
connect to the TRACKx pins. Limit the capacitance at the
RAMPBUF pin to less than 100pF.
GND (Pin 6): Circuit Ground.
Exposed Pad (Pin 13): The exposed pad may be left open
or connected to GND.
FB1, FB2 (Pins 8, 7): Feedback Control Output. FBx pulls
up on the feedback node of slave supplies. Tracking is
achieved by mirroring the current from TRACKx into FBx.
If the appropriate resistive divider connects RAMPBUF and
TRACKx, the FBx current will force OUTx to track RAMP. To
prevent damage to the slave supply, the FBx pin will not
force the slave’s feedback node above 1.7V. In addition,
it will not actively sink current from this node even when
the LTC2923 is unpowered. Float the FB pins if unused.
6
GATE (Pin 9/Pin 11): Gate Drive for External N-Channel FET.
When the ON pin is high, an internal 10µA current source
charges the gate of the external N-channel MOSFET. A
capacitor connected from GATE to GND sets the ramp rate.
An internal charge pump guarantees that GATE will pull up
to 5V above VCC ensuring that logic level N-channel FETs
are fully enhanced. When the ON pin is pulled low, the GATE
pin is pulled to GND with a 10µA current source. Under
a short-circuit condition, the electronic circuit breaker in
the LTC2923 pulls the GATE low immediately with 20mA.
Tie GATE to GND if unused. It is a good practice to add a
10Ω resistor between this capacitor and the FET’s gate
to prevent high frequency FET oscillations.
RAMP (Pin 10/Pin 12): Ramp Buffer Input. When the
RAMP pin is connected to the source of the external
N-channel FET, the slave supplies track the FET’s source
as it ramps up and down. If the GATE is fully enhanced
(GATE > RAMP + 4.9V) and (VCC – RAMP > 200mV) indicates a shorted output, then the electronic circuit breaker
trips and GATE quickly pulls low with 20mA. The GATE
will not ramp up again until ON is pulled below 0.4V and
then above 1.23V. Alternatively, when no external FET is
used, the RAMP pin can be tied directly to the GATE pin.
In this configuration, the supplies track the capacitor on
the GATE pin as it is charged and discharged by the 10µA
current source controlled by the ON pin. RAMP must not
be driven above VCC (except by the GATE pin).
SDO (Pin 9, DE Package Only): Slave Supply Shutdown
Output. SDO is an open-drain output that holds the shutdown (RUN/SS) pins of the slave supplies low until the ON
pin is pulled above 1.23V. If the slave supply is capable
of operating with an input supply that is lower than the
LTC2923’s minimum operating voltage of 2.9V, the SDO
pin can be used to hold off the slave supplies. SDO will be
pulled low again when RAMP < 100mV and ON < 1.23V.
STATUS (Pin 10, DE Package Only): Power Good Status
Indicator. The STATUS pin is an open-drain output that
pulls low until GATE has been fully charged at which time
all supplies will have reached their final operating voltage.
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LTC2923
functional Block Diagram
1
VCC
CHARGE
PUMP
10µA
2
ON
1.2V
0.4V
10
+
–
–
+
GATE
SHORT-CIRCUIT
FAULT LATCH
R
Q
S
Q
11 (9)
ONSIG
10µA
STATUS
GATE > RAMP + 4.9V
4.9V
GATE
RAMP > VCC
VCC
RAMP
12 (10)
+
–
VCC – RAMP > 200mV
0.2V
VCC
RAMP < 100mV
+
–
9
SDO
ONSIG
VCC < 2.6V
–
+
5
RAMPBUF
0.1V
VCC
2.6V
1×
VCC
3
4
+
–
TRACK1
0.8V
FB1
VCC
+
–
TRACK2
PIN NUMBERS IN PARENTHESES CORRESPOND
TO THE 10-LEAD MSOP PACKAGE
6
8
0.8V
FB2
GND
7
2923 FBD
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7
LTC2923
Applications Information
Power Supply Tracking and Sequencing
The LTC2923 handles a variety of power-up profiles to
satisfy the requirements of digital logic circuits including
FPGAs, PLDs, DSPs and microprocessors. These requirements fall into one of the four general categories illustrated
in Figures 1 to 4.
Some applications require that the potential difference
between two power supplies must never exceed a specified voltage. This requirement applies during power-up
and power-down as well as during steady-state operation,
often to prevent destructive latch-up in a dual supply
ASIC. Typically, this is achieved by ramping the supplies
up and down together (Figure 1). In other applications it
is desirable to have the supplies ramp up and down with
fixed voltage offsets between them (Figure 2) or to have
them ramp up and down ratiometrically (Figure 3).
Certain applications require one supply to come up after
another. For example, a system clock may need to start
before a block of logic. In this case, the supplies are sequenced as in Figure 4 where the 2.5V supply ramps up
after the 1.8V supply is completely powered.
Operation
The LTC2923 provides a simple solution to all of the power
supply tracking and sequencing profiles shown in Figures 1
to 4. A single LTC2923 controls up to three supplies with
two “slave” supplies that track a “master” signal. With
just two resistors, a slave supply is configured to ramp up
as a function of the master signal. This master signal can
be a third supply that is ramped up through an external
FET, whose ramp rate is set with a single capacitor, or it
can be a signal generated by tying the GATE and RAMP
pins to an external capacitor.
MASTER
SLAVE1
SLAVE2
1V/DIV
1ms/DIV
MASTER
SLAVE1
SLAVE2
1V/DIV
2923 F01
1ms/DIV
Figure 1. Coincident Tracking
2923 F02
Figure 2. Offset Tracking
MASTER
SLAVE1
SLAVE2
1V/DIV
1ms/DIV
2923 F03
Figure 3. Ratiometric Tracking
8
SLAVE1
SLAVE2
1V/DIV
1ms/DIV
2923 F04
Figure 4. Supply Sequencing
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LTC2923
Applications Information
Tracking Cell
In a properly designed system, when the master signal
has reached its maximum voltage the current from the
TRACKx pin is zero. In this case, there is no current from
the FBx pin and the LTC2923 has no effect on the output
voltage accuracy, transient response or stability of the
slave supply.
The LTC2923’s operation is based on the tracking cell
shown in Figure 5, which uses a proprietary wide-range
current mirror. The tracking cell shown in Figure 5 servos
the TRACK pin at 0.8V. The current supplied by the TRACK
pin is mirrored at the FB pin to establish a voltage at the
output of the slave supply. The slave output voltage varies
with the master signal, enabling the slave supply to be
controlled as a function of the master signal with terms
set by RTA and RTB. By selecting appropriate values of
RTA and RTB, it is possible to generate any of the profiles
in Figures 1 to 4.
When the ON pin falls below VON(TH) – ∆VON(HYST), typically 1.225V, the GATE pin pulls down with 10µA and the
master signal and the slave supplies will fall at the same
rate as they rose previously.
The ON pin can be controlled by a digital I/O pin or it
can be used to monitor an input supply. By connecting a
resistive divider from an input supply to the ON pin, the
supplies will ramp up only after the monitored supply has
reached a preset voltage.
Controlling the Ramp-Up and Ramp-Down Behavior
The operation of the LTC2923 is most easily understood by
referring to the simplified functional diagram in Figure 6.
When the ON pin is low, the GATE pin is pulled to ground
causing the master signal to remain low. Since the currents
through RTB1 and RTB2 are at their maximum when the
master signal is low, the currents from FB1 and FB2 are
also at their maximum. These currents drive the slaves’
outputs to their minimum voltages.
Optional External FET
The Coincident Tracking Example (Figures 8 and 9) illustrates how an optional external N-channel FET can ramp
up a single supply that becomes the master signal. When
used, the FET’s gate is charged by the GATE pin and its
source is tied to the RAMP pin. Under normal operation,
the GATE pin sources or sinks 10µA to ramp the FET’s
gate up or down at a rate set by the external capacitor
connected to the GATE pin. It is a good practice to add
10Ω between the FET’s gate and the external capacitor to
prevent high frequency oscillations.
When the ON pin rises above 1.23V, the master signal rises
and the slave supplies track the master signal. The ramp
rate is set by an external capacitor driven by a 10µA current
source from an internal charge pump. If no external FET
is used, the ramp rate is set by tying the RAMP and GATE
pins together at one terminal of the external capacitor (see
the Ratiometric Tracking Example).
VCC
+
MASTER
RTB
–
TRACK
+
–
0.8V
DC/DC
FB
FB OUT
RTA
RFA
SLAVE
RFB
2923 F05
Figure 5. Simplified Tracking Cell
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9
LTC2923
Applications Information
VCC
RONB
ON
RONA
1.2V
10µA
+
GATE
–
CGATE
10µA
VCC
+–
Q1
+
200mV
–
RAMPBUF
RAMP
1×
MASTER
VCC
+
RTB1
0.8V
–
FB1
TRACK1
VCC
RTA1
DC/DC
RFA1
+
RTB2
SLAVE1
RFB1
0.8V
–
FB2
TRACK2
DC/DC
RTA2
RFA2
SLAVE2
RFB2
2923 F06
Figure 6. Simplified Functional Diagram
The LTC2923 features an electronic circuit breaker function
that protects the optional series FET against short circuits.
When the FET is fully enhanced (GATE > RAMP + 4.9V),
the electronic circuit breaker is enabled. Then, if the voltage across the FET (VDS) exceeds 200mV as measured
from VCC to the RAMP pin for more than about 10µs the
gate of the FET is pulled down with 20mA, turning it off.
Because the slaved supplies track the RAMP pin, they are
pulled low by the tracking circuit when a short-circuit fault
occurs. Following a short-circuit fault, the FET is latched off
until the fault is cleared by pulling the ON pin below 0.4V.
10
Ramp Buffer
The RAMPBUF pin provides a buffered version of the
RAMP pin voltage that drives the resistive dividers on the
TRACKx pins. When there is no external FET, it provides
up to 2mA to drive the resistors even though the GATE
pin only supplies 10µA. The RAMPBUF pin also proves
useful in systems with an external FET. Since the track
cell in the simplified functional diagram above drives 0.8V
on the TRACKx pins, if RTBx is connected directly to the
FET’s source, the TRACKx pin could potentially pull up the
FET’s source towards 0.8V when the FET is off. RAMPBUF
blocks this path.
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LTC2923
Applications Information
Shutdown Output
In some applications it might be necessary to control the
shutdown or RUN/SS pins of the slave supplies using the
12-lead LTC2923CDE or LTC2923IDE. The LTC2923 may
not be able to supply the rated 1mA of current from the FB1
and FB2 pins when VCC is below 2.9V. If the slave power
supplies are capable of operating at low input voltages, use
the open-drain SDO output to drive the SHDN or RUN/SS
pins of the slave supplies (see Figure 7). This will hold the
slave supplies’ outputs low until the ON pin is above 1.23V,
VCC is above the 2.6V undervoltage lockout condition and
there are no short-circuit faults latched. It pulls low again
when the ON pin is pulled below 1.23V and the RAMP pin
is below about 100mV. When two supplies must have
Q1
VIN
3.3V
0.1µF
10Ω
their RUN/SS or SHDN pins controlled independently, tie
a Schottky diode between each pin and the SDO output
(see Figure 8).
Status Output
The STATUS pin provides an indication that the supplies
are finished ramping up. This pin is an open-drain output
that pulls low until the GATE has been fully charged. Since
the GATE pin drives the gate of the external FET, or the
RAMP pin directly when no FET is used, the supplies are
completely ramped up when the GATE pin is fully charged.
It will go low again when the GATE pin is pulled low, either
because of a short-circuit fault or because the ON pin has
been pulled low.
Q1
VIN
3.3V
3.3V
0.1µF
CGATE
10nF
10Ω
VIN
3.3V
CGATE
10nF
VIN
RSTATUS
10k
RONB
138k
RONA
100k
VCC
GATE
RAMP
FB1
LTC2923
RTB1
16.5k
RTA1
13k
RTB2
887k
RTA2
412k
TRACK1
RONA
100k
OUT
FB2
GATE
RAMP
FB1
RFB1
16.5k
GND
RFB2
887k
OUT
2.5V
RTA1
13k
RTB2
887k
RTA2
412k
TRACK1
OUT
1.8V
OUT
2.5V
RFB1
16.5k
VIN
SDO
FB2
TRACK2
RUN/SS IN
DC/DC
FB = 1.235V
RFA1
35.7k
RAMPBUF
RTB1
16.5k
VIN
STATUS
LTC2923
RUN/SS IN
DC/DC
FB = 0.8V
RFA2
412k
VCC
ON
1.8V
VIN
SDO
TRACK2
RUN/SS IN
DC/DC
FB = 1.235V
RFA1
35.7k
RAMPBUF
RONB
138k
VIN
STATUS
ON
RSTATUS
10k
RUN/SS IN
DC/DC
FB = 0.8V
GND
RFA2
412k
2923 F07
RFB2
887k
2923 F08
Figure 7
Figure 8
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11
LTC2923
Applications Information
3-Step Design Procedure
The following 3-step procedure allows one to complete
a design for any of the tracking or sequencing profiles
shown in Figures 1 to 4. A basic three supply application
circuit is shown in Figure 9.
1.Set the ramp rate of the master signal.
Solve for the value of CGATE, the capacitor on the GATE
pin, based on the desired ramp rate (V/s) of the master
supply, SM.
CGATE =
IGATE
where IGATE ≈ 10μA
SM
If no external FET is used, tie the GATE and RAMP pins
together.
2.Solve for the pair of resistors that provide the desired
ramp rate of the slave supply, assuming no delay.
Choose a ramp rate for the slave supply, SS. If the slave
supply ramps up coincident with the master supply or
with a fixed voltage offset, then the ramp rate equals
the master supply’s ramp rate. Be sure to use a fast
enough ramp rate for the slave supply so that it will
finish ramping before the master supply has reached
its final supply value. If not, the slave supply will be
held below the intended regulation value by the master
supply. Use the following formulas to determine the
resistor values for the desired ramp rate, where RFB
and RFA are the feedback resistors in the slave supply
and VFB is the feedback reference voltage of the slave
supply:
RTA ʹ =
SM
SS VTRACK
VFB VFB VTRACK
+
–
RFB RFA
RTB 3.Choose RTA to obtain the desired delay.
If no delay is required, such as in coincident and ratiometric tracking, then simply set RTA = RTA′. If a delay
is desired, as in offset tracking and supply sequencing,
calculate RTA′′ to determine the value of RTA where tD
is the desired delay in seconds.
(1)
If the external FET has a gate capacitance comparable
to CGATE, then the external capacitor’s value should be
reduced to compensate for the FET’s gate capacitance.
RTB = RFB •
Note that large ratios of slave ramp rate to master ramp
rate, SS/SM, may result in negative values for RTA′. If
sufficiently large delay is used in step 3, RTA will be
positive, otherwise SS/SM must be reduced.
RTA ʹʹ =
VTRACK • RTB
tD • SM RTA = RTA′||RTA′′(5)
the parallel combination of RTA′ and RTA′′
As noted in step 2, small delays and large ratios of slave
ramp rate to master ramp rate (usually only seen in sequencing) may result in solutions with negative values for
RTA. In such cases, either the delay must be increased or
the ratio of slave ramp rate to master ramp rate must be
reduced.
Q1
VIN
0.1µF
10Ω
MASTER
CGATE
VIN
RONB
VCC
GATE
ON
RONA
RAMP
FB1
FB
RFA1
RAMPBUF
RTB1
OUT
SLAVE1
OUT
SLAVE2
IN
DC/DC
RTB2
RTA2
FB2
FB
GND
RFA2
(3)
RFB1
VIN
TRACK1
RTA1
IN
DC/DC
LTC2923
TRACK2
(2)
(4)
RFB2
2923 F09
Figure 9. Three Supply Application
where VTRACK ≈ 0.8V.
12
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LTC2923
Applications Information
Coincident Tracking Example
MASTER
SLAVE2
1V/DIV
1V/DIV
SLAVE1
2923 F10a
1ms/DIV
2923 F10b
1ms/DIV
Figure 10. Coincident Tracking (from Figure 11)
A typical three supply application is shown in Figure 11.
The master signal is a 3.3V module. The slave 1 supply is
a 1.8V switching power supply and the slave 2 supply is
a 2.5V switching power supply. Both slave supplies track
coincidently with the 3.3V supply that is controlled with
an external FET. The ramp rate of the supplies is 1000V/s.
The 3-step design procedure detailed previously can be
used to determine component values. Only the slave 1
supply is considered here as the procedure is the same
for the slave 2 supply.
1.Set the ramp rate of the master signal.
From Equation 2:
1000 V/s
= 16.5kΩ
1000 V/s
From Equation 3:
RTA ʹ =
0.8 V
≈ 13kΩ
1.235V 1.235V
0.8 V
+
–
16.5kΩ 35.7kΩ 16.5kΩ
3.Choose RTA to obtain the desired delay.
Since no delay is desired, RTA = RTA′
3.3V
MASTER
CGATE
10nF
3.3V
RONB
138k
RONA
100k
VCC
GATE
ON
RAMP
FB1
LTC2923
RTB2
887k
TRACK1
FB2
TRACK2
GND
1.8V
SLAVE1
RFA1 RFB1 16.5k
35.7k 3.3V
RAMPBUF
RTB1
16.5k
IN
DC/DC
FB = 1.235V OUT
IN
DC/DC
FB = 0.8V
OUT
RFA2
412k
2.5V
SLAVE2
RFB2
887k
2923 F11
2.Solve for the pair of resistors that provide the desired
slave supply behavior, assuming no delay.
10Ω
RTA2
412k
10μA
CGATE =
= 10nF
1000 V/s
RTB = 16.5kΩ •
0.1µF
RTA1
13k
From Equation 1:
Q1
3.3V
Figure 11. Coincident Tracking Example
In this example, all supplies remain low while the ON pin
is held below 1.23V. When the ON pin rises above 1.23V,
10µA pulls up CGATE and the gate of the FET at 1000V/s.
As the gate of the FET rises, the source follows and pulls
up the output to 3.3V at 1000V/s. This output serves as
the master signal and is buffered from the RAMP pin
to the RAMPBUF pin. As this output and the RAMPBUF
pin rise, the current from the TRACK pins is reduced.
Consequently, the voltage at the slave supply’s outputs
increases, and the slave supplies track the master supply.
When the ON pin is again pulled below 1.23V, 10µA will
pull down CGATE and the gate of the FET at 1000V/s. If the
loads on the outputs are sufficient, all outputs will track
down coincidently at 1000V/s.
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LTC2923
Applications Information
Ratiometric Tracking Example
SLAVE2
1V/DIV
1V/DIV
SLAVE1
1ms/DIV
2923 F12a
2923 F12b
1ms/DIV
Figure 12. Ratiometric Tracking (from Figure 13)
This example converts the coincident tracking example to
the ratiometric tracking profile shown in Figure 12, using
two supplies without an external FET. The ramp rate of
the master signal remains unchanged (Step 1) and there
is no delay in ratiometric tracking (Step 3), so only the
result of step 2 in the 3-step design procedure needs to
be considered. In this example, the ramp rate of the 1.8V
slave 1 supply ramps up at 600V/s and the 2.5V slave 2
supply ramps up at 850V/s. Always verify that the chosen
ramp rate will allow the supplies to ramp-up completely
before RAMPBUF reaches VCC. If the 1.8V supply were to
ramp-up at 500V/s it would only reach 1.65V because the
RAMPBUF signal would reach its final value of VCC = 3.3V
before the slave supply reached 1.8V.
2.Solve for the pair of resistors that provide the desired
slave supply behavior, assuming no delay.
From Equation 2:
RTB = 16.5kΩ •
1000 V/s
≈ 27.4kΩ
600 V/s
From Equation 3:
RTA ʹ =
0.8 V
= 10kΩ
1.235V 1.235V
0.8 V
+
–
16.5kΩ 35.7kΩ 27.5kΩ
Step 3 is unnecessary because there is no delay, so
RTA = RTA′.
3.3V
CGATE
10nF
0.1µF
RONB
138k
VCC GATE
ON
RONA
100k
RAMP
FB1
LTC2923
RTB2
1M
RTA2
383k
TRACK1
FB2
TRACK2
IN
DC/DC
FB = 1.235V OUT
1.8V
SLAVE1
RFA1 RFB1
35.7k 16.5k
3.3V
RAMPBUF
RTB1
27.4k
RTA1
10k
3.3V
IN
DC/DC
FB = 0.8V
OUT
GND
RFA2
412k
2.5V
SLAVE2
RFB2
887k
2923 F13
Figure 13. Ratiometric Tracking Example
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LTC2923
Applications Information
Offset Tracking Example
MASTER
SLAVE2
1V/DIV
1V/DIV
SLAVE1
2923 F14a
1ms/DIV
2923 F14b
1ms/DIV
Figure 14. Offset Tracking (from Figure 15)
Converting the circuit in the coincident tracking example
to the offset tracking shown in Figure 14 is relatively
simple. Here the 1.8V slave 1 supply ramps up 1V below
the master. The ramp rate remains the same (1000V/s),
so there are no changes necessary to steps 1 and 2 of the
3-step design procedure. Only step 3 must be considered.
Be sure to verify that the chosen voltage offsets will allow
the slave supplies to ramp up completely. In this example,
if the voltage offset were 2V, the slave supply would only
ramp up to 3.3V – 2V = 1.3V.
3.Choose RTA to obtain the desired delay.
First, convert the desired voltage offset, VOS, to a delay,
tD, using the ramp rate:
V
1V
tD = OS =
= 1ms
S
1000
V
/
s
S
From Equation 4:
RTA ʹʹ =
Q1
3.3V
3.3V
MASTER
0.1µF
10Ω
CGATE
10nF
3.3V
RONB
138k
RONA
100k
GATE
RAMP
FB1
LTC2923
RTB2
887k
RTA2
316k
TRACK1
FB2
TRACK2
IN
DC/DC
FB = 1.235V OUT
IN
DC/DC
FB = 0.8V
OUT
GND
RFA2
412k
(6)
1.8V
SLAVE1
RFA1 RFB1
35.7k 16.5k
3.3V
RAMPBUF
RTB1
16.5k
RTA1
6.65k
VCC
ON
2.5V
SLAVE2
RFB2
887k
2923 F15
Figure 15. Offset Tracking Example
0.8 V • 16.5kΩ
= 13.2kΩ
1ms • 1000 V/s
From Equation 5:
RTA = 13.1kΩ||13.2kΩ ≈ 6.65kΩ
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LTC2923
Applications Information
Supply Sequencing Example
MASTER
SLAVE2
1V/DIV
1V/DIV
SLAVE1
10ms/DIV
2923 F16a
2923 F16b
10ms/DIV
Figure 16. Supply Sequencing (from Figure 17)
In Figure 16, the slave 1 supply and the slave 2 supply are
sequenced instead of tracking. The 3.3V supply ramps up
at 100V/s with an external FET and serves as the master
signal. The 1.8V slave 1 supply ramps up at 1000V/s beginning 10ms after the master signal starts to ramp up.
The 2.5V slave 2 supply ramps up at 1000V/s beginning
25ms after the master signal begins to ramp up. Note
that not every combination of ramp rates and delays is
possible. Small delays and large ratios of slave ramp rate
to master ramp rate may result in solutions that require
negative resistors. In such cases, either the delay must
be increased or the ratio of slave ramp rate to master
ramp rate must be reduced. In this example, solving for
the slave 1 supply yields:
1.Set the ramp rate of the master signal.
From Equation 3:
RTA ʹ =
3.Choose RTA to obtain the desired delay.
From Equation 4:
RTA ʹʹ =
RTA = – 2.13kΩ||1.32kΩ = 3.48kΩ
Q1
3.3V
0.1µF
10Ω
10μA
= 100nF
100 V/s
From Equation 2:
RTB = 16.5kΩ •
100 V/s
= 1.65kΩ
1000 V/s
3.3V
MASTER
CGATE
100nF
3.3V
RONB
138k
2.Solve for the pair of resistors that provide the desired slave supply behavior, assuming no delay.
0.8 V • 1.65kΩ
= 1.32kΩ
10ms • 100 V/s
From Equation 5:
From Equation 1:
CGATE =
0.8 V
= –2.13kΩ
1.235V 1.235V
0.8 V
+
–
16.5kΩ 35.7kΩ 1.65kΩ
RONA
100k
GATE
ON
RAMP
FB1
LTC2923
RTB2
88.7k
RTA2
36.5k
TRACK1
FB2
TRACK2
GND
IN
DC/DC
FB = 1.235V OUT
1.8V
SLAVE1
RFA1 RFB1 16.5k
35.7k
3.3V
RAMPBUF
RTB1
1.65k
RTA1
3.48k
VCC
IN
DC/DC
FB = 0.8V
OUT
2.5V
SLAVE2
2923 F17
RFA2
412k
RFB2
887k
Figure 17. Supply Sequencing Example
16
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LTC2923
Applications Information
Final Sanity Checks
The collection of equations below is useful for identifying
unrealizable solutions.
As stated in step 2, the slave supply must finish ramping
before the master signal has reached its final voltage. This
can be verified by the following equation:
⎛ R ⎞
VTRACK ⎜ 1 + TB ⎟ < VCC, where VTRACK = 0.8 V
⎝ RTA ⎠
It is possible to choose resistor values that require the
LTC2923 to supply more current than the Electrical Characteristics table guarantees. To avoid this condition, check
that ITRACKx does not exceed 1mA and IRAMPBUF does not
exceed ±2mA.
To confirm that ITRACKx < 1mA, the TRACKx pin’s maximum
guaranteed current, verify that:
VTRACK
< 1mA
R
R
TA
TB
Finally, check that the RAMPBUF pin will not be forced
to sink more then 2mA when it is at 0V or be forced to
source more than 2mA when it is at VCC.
VTRACK VTRACK
+
< 2mA and
RTB1
RTB2
VCC
VCC
+
< 2mA
RTA1 + RTB1 RTA2 + RTB2
falls below the input voltage. Therefore, the LTC2923’s
tracking cell will not effectively drive the supply’s output
below the input.
Special caution should be taken when considering the
use of linear regulators. Three-terminal linear regulators
have a reference voltage that is referred to the output
supply rather than to ground. In this case, driving current
into the regulator’s feedback node will cause its output
to rise rather than fall. Even linear regulators that have
their reference voltage referred to ground, including low
dropout regulators (LDOs), may be problematic. Linear
regulators commonly contain circuitry that prevents driving
their outputs below their reference voltage. This may not
be obvious from the data sheets, so lab testing is recommended whenever the LTC2923’s tracking cell is used to
control linear regulators.
Load Requirements
When the supplies are ramped down quickly, either the
load or the supply itself must be capable of sinking enough
current to support the ramp rate. For example, if there
is a large output capacitance on the supply and a weak
resistive load, supplies that do not sink current will have
their falling ramp rate limited by the RC time constant of
the load and the output capacitance. Figure 18 shows the
case when the 2.5V supply does not track the 1.8V and
3.3V supplies near ground.
Start-Up Delays
Caution with Boost and Linear Regulators
Note that the LTC2923’s tracking cell is not able to control
the outputs of all types of power supplies. If it is necessary to control one of these types of supplies, where the
output is not controllable through its feedback node, the
series FET can be used to control one supply’s output. For
example, boost regulators commonly contain an inductor
and diode between the input supply and the output supply providing a DC current path when the output voltage
Often power supplies do not start-up immediately when
their input supplies are applied. If the LTC2923 tries to
ramp-up these power supplies as soon as the input supply is present, the start-up of the outputs may be delayed,
defeating the tracking circuit (Figure 19). Often this delay
is intentionally configured by a soft-start capacitor. This
can be remedied either by reducing the soft-start capacitor
on the slave supply or by including a capacitor in the ON
pin’s resistive divider to delay the ramp up. See Figure 20.
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LTC2923
Applications Information
Layout Considerations
MASTER
SLAVE1
SLAVE2
1V/DIV
2923 F18
1ms/DIV
Figure 18. Weak Resistive Load
MASTER
SLAVE1
1V/DIV
Be sure to place a 0.1µF bypass capacitor as near as possible to the supply pin of the LTC2923. A 10Ω resistor
located near the FET and connected between the FET’s
gate and the external CGATE capacitor is recommended.
This will almost assuredly eliminate the troublesome
high frequency oscillations that can occur due to the FET
interacting with PCB parasitics.
To minimize the noise on the slave supplies’ outputs, keep
the traces connecting the FBx pins of the LTC2923 and the
feedback nodes of the slave supplies as short as possible.
In addition, do not route those traces next to signals with
fast transition times. In some circumstances it might be
advantageous to add a resistor near the feedback node of
the slave supply in series with the FBx pin of the LTC2923.
This resistor must not exceed:
SLAVE2
ON
1ms/DIV
2923 F19
Figure 19. Power Supply Start-Ups Delayed
RSERIES =
1.5V – VFB ⎛ 1.5V ⎞
=⎜
– 1⎟ (RFA || RFB)
⎝ VFB
⎠
IMAX
This resistor is most effective if there is already a capacitor at the feedback node of the slave supply (often a
compensation component). Increasing the capacitance on
a slave supply’s feedback node will further improve the
noise immunity, but could affect the stability and transient
response of the supply.
MASTER
SLAVE1
1V/DIV
10Ω
FET
VCC
CGATE
OUT
SLAVE2
VCC
LTC2923
RAMP
ON
GATE
FB1
1ms/DIV
2923 F19
GND
0.1µF
Figure 20. ON Pin Delayed
RSERIES
MINIMIZE
TRACE
LENGTH
DC/DC
FB
OUT
RFA
RFB
2923 F21
Figure 21. Layout Considerations
18
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LTC2923
Package Description
Please refer to http://www.linear.com/product/LTC2923#packaging for the most recent package drawings.
MS Package
10-Lead Plastic MSOP
(Reference LTC DWG # 05-08-1661 Rev F)
0.889 ±0.127
(.035 ±.005)
5.10
(.201)
MIN
3.20 – 3.45
(.126 – .136)
3.00 ±0.102
(.118 ±.004)
(NOTE 3)
0.50
0.305 ±0.038
(.0197)
(.0120 ±.0015)
BSC
TYP
RECOMMENDED SOLDER PAD LAYOUT
0.254
(.010)
10 9 8 7 6
3.00 ±0.102
(.118 ±.004)
(NOTE 4)
4.90 ±0.152
(.193 ±.006)
DETAIL “A”
0.497 ±0.076
(.0196 ±.003)
REF
0° – 6° TYP
GAUGE PLANE
1 2 3 4 5
0.53 ±0.152
(.021 ±.006)
DETAIL “A”
0.18
(.007)
SEATING
PLANE
0.86
(.034)
REF
1.10
(.043)
MAX
0.17 – 0.27
(.007 – .011)
TYP
0.50
(.0197)
BSC
NOTE:
1. DIMENSIONS IN MILLIMETER/(INCH)
2. DRAWING NOT TO SCALE
3. DIMENSION DOES NOT INCLUDE MOLD FLASH, PROTRUSIONS OR GATE BURRS.
MOLD FLASH, PROTRUSIONS OR GATE BURRS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
4. DIMENSION DOES NOT INCLUDE INTERLEAD FLASH OR PROTRUSIONS.
INTERLEAD FLASH OR PROTRUSIONS SHALL NOT EXCEED 0.152mm (.006") PER SIDE
5. LEAD COPLANARITY (BOTTOM OF LEADS AFTER FORMING) SHALL BE 0.102mm (.004") MAX
0.1016 ±0.0508
(.004 ±.002)
MSOP (MS) 0213 REV F
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19
LTC2923
Package Description
Please refer to http://www.linear.com/product/LTC2923#packaging for the most recent package drawings.
DE/UE Package
12-Lead Plastic DFN (4mm × 3mm)
(Reference LTC DWG # 05-08-1695 Rev D)
0.70 ±0.05
3.30 ±0.05
3.60 ±0.05
2.20 ±0.05
1.70 ±0.05
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
2.50 REF
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
4.00 ±0.10
(2 SIDES)
7
R = 0.115
TYP
0.40 ±0.10
12
R = 0.05
TYP
PIN 1
TOP MARK
(NOTE 6)
0.200 REF
3.30 ±0.10
3.00 ±0.10
(2 SIDES)
1.70 ±0.10
0.75 ±0.05
6
0.25 ±0.05
1
PIN 1 NOTCH
R = 0.20 OR
0.35 × 45°
CHAMFER
(UE12/DE12) DFN 0806 REV D
0.50 BSC
2.50 REF
0.00 – 0.05
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING PROPOSED TO BE A VARIATION OF VERSION
(WGED) IN JEDEC PACKAGE OUTLINE M0-229
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
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LTC2923
Revision History
(Revision history begins at Rev B)
REV
DATE
DESCRIPTION
B
06/16
Updated Order Information.
PAGE NUMBER
Updated MS and DE/UE Package Descriptions.
2
19, 20
2923fb
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection
of its circuits
as described
herein will not infringe on existing patent rights.
For more
information
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21
LTC2923
Typical Applications
Daisy-Chained Application
3.3V
High Voltage Supply Application
3.3V
0.1µF
VCC
GATE
ON
FB1
IN
DC/DC
FB = 1.235V OUT
CGATE
10nF
3.3V
SLAVE1
RONB
138k
LTC2923
RTB1
RTB2
RTA1
TRACK1
FB2
TRACK2
GND
RTA2
RFB1
RFA1
RAMPBUF
IN
DC/DC
FB = 0.8V
OUT
RAMP
ON
RAMP
FB1
RTB2
RFA1
TRACK1
RTA2
FB2
CGATE
10nF
RONA
100k
RTA
RAMP
ON
RTB
5V
SLAVE2
RFB2
2923 TA04
FB1
IN
DC/DC
FB = 1.235V OUT
1.8V
SLAVE1
LTC2923
TRACK1
FB2
TRACK2
RTA
RFB
RFA
RAMPBUF
RTB
IN
DC/DC
FB = 0.8V
OUT
RFA2
VCC GATE
12V
SLAVE1
RFB1
GND
0.1µF
RONB
138k
IN
DC/DC
FB = 1.235V OUT
LTC2923
RAMPBUF
RTB1
RTA1
VCC GATE
TRACK2
RFB2
RFA2
3.3V
RONA
100k
2.5V
SLAVE2
0.1µF
IN
DC/DC
FB = 0.8V
OUT
GND
1.5V
SLAVE2
RFB
RFA
2923 TA03
Related Parts
PART NUMBER
DESCRIPTION
COMMENTS
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LTC2921/LTC2922
Power Supply Tracker with Input Monitors
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LTC2925
Multiple Power Supply Tracking Controller
Up to 4 Supplies, Status and Fault Pins, Slave Supply Shutdown, Remote
Sense Switch
LT®4220
Dual Supply Hot Swap Controller
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LTC4230
Triple Hot Swap Controller with Multifunction
Current Control
1.7V to 16.5V, Active Inrush Limiting, Fast Comparator
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–48V Hot Swap Controller and Supply Sequencer
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Enables Three DC/DC Converters
22 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
For more information www.linear.com/LTC2923
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com/LTC2923
2923fb
LT 0616 REV B • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2003