LT8580
1
8580f
For more information www.linear.com/LT8580
Typical applicaTion
FeaTures
applicaTions
DescripTion
Boost/SEPIC/Inverting
DC/DC Converter with 1A, 65V
Switch, Soft-Start and Synchronization
The LT
®
8580 is a PWM DC/DC converter containing an
internal 1A, 65V switch. The LT8580 can be configured
as either a boost, SEPIC or inverting converter.
The LT8580 has an adjustable oscillator, set by a resistor
from the RT pin to ground. Additionally, the LT8580 can be
synchronized to an external clock. The switching frequency
of the part may be free running or synchronized, and can
be set between 200kHz and 1.5MHz.
The LT8580 also features innovative SHDN pin circuitry
that allows for slowly varying input signals and an adjust-
able undervoltage lockout function.
Additional features such as frequency foldback and
soft-start are integrated. The LT8580 is available in tiny
thermally enhanced 3mm × 3mm 8-lead DFN and 8-lead
MSOP packages.
1.5MHz, 5V to 12V Boost Converter
n 1A, 65V Power Switch
n Adjustable Switching Frequency
n Single Feedback Resistor Sets VOUT
n Synchronizable to External Clock
n High Gain SHDN Pin Accepts Slowly Varying
Input Signals
n Wide Input Voltage Range: 2.55V to 40V
n Low VCESAT Switch: 400mV at 0.75A (Typical)
n Integrated Soft-Start Function
n Easily Configurable as a Boost, SEPIC, or Inverting
Converter
n User Configurable Undervoltage Lockout (UVLO)
n Pin Compatible with LT3580
n Tiny Thermally Enhanced 8-Lead 3mm × 3mm DFN
and 8-Lead MSOP Packages
n VFD Bias Supplies
n TFT-LCD Bias Supplies
n GPS Receivers
n DSL Modems
n Local Power Supply
Efficiency and Power Loss
L, LT, LTC , LT M, Linear Technology and the Linear logo are registered trademarks and
ThinSOT is a trademark of Linear Technology Corporation. All other trademarks are the
property of their respective owners. Protected by U.S. Patents, including 7579816.
LOAD CURRENT (mA)
0
20
EFFICIENCY (%)
POWER LOSS (mW)
40
50
60
100
100
8580 TA01b
30
50 150 200
70
80
90
0
180
300
480
240
60
120
360
420
EFFICIENCY
POWER LOSS
4.7µF
VOUT
12V
200mA
15µH
130k
VIN
5V
VIN SW
8580 TA01a
LT8580
10k
6.04k
56.2k
SHDN
GND
FBX
VCSYNC
SSRT
3.3nF
47pF
0.22µF
2.2µF
LT8580
2
8580f
For more information www.linear.com/LT8580
absoluTe MaxiMuM raTings
VIN Voltage .................................................0.3V to 40V
SW Voltage ................................................0.4V to 65V
RT Voltage ...................................................0.3V to 5V
SS Voltage ................................................0.3V to 2.5V
FBX Voltage .................................................................5V
FBX Current ............................................................–1mA
VC Voltage ...................................................0.3V to 2V
(Note 1)
TOP VIEW
DD PACKAGE
8-LEAD (3mm × 3mm) PLASTIC DFN
5
6
7
8
9
GND
4
3
2
1FBX
VC
VIN
SW
SYNC
SS
RT
SHDN
θJA = 43°C/W
EXPOSED PAD (PIN 9) IS GND, MUST BE SOLDERED TO PCB
1
2
3
4
FBX
VC
VIN
SW
8
7
6
5
SYNC
SS
RT
SHDN
TOP VIEW
9
GND
MS8E PACKAGE
8-LEAD PLASTIC MSOP
θJA = 35°C/W TO 40°C/W
EXPOSED PAD (PIN 9) IS GND, MUST BE SOLDERED TO PCB
pin conFiguraTion
orDer inForMaTion
LEAD FREE FINISH TAPE AND REEL PART MARKING* PACKAGE DESCRIPTION TEMPERATURE RANGE
LT8580EDD#PBF LT8580EDD#TRPBF LGKH 8-Lead (3mm × 3mm) Plastic DFN 40°C to 125°C
LT8580IDD#PBF LT8580IDD#TRPBF LGKH 8-Lead (3mm × 3mm) Plastic DFN 40°C to 125°C
LT8580HDD#PBF LT8580HDD#TRPBF LGKH 8-Lead (3mm × 3mm) Plastic DFN 40°C to 150°C
LT8580EMS8E#PBF LT8580EMS8E#TRPBF LTGKJ 8-Lead Plastic MSOP 40°C to 125°C
LT8580IMS8E#PBF LT8580IMS8E#TRPBF LTGKJ 8-Lead Plastic MSOP 40°C to 125°C
LT8580HMS8E#PBF LT8580HMS8E#TRPBF LTGKJ 8-Lead Plastic MSOP 40°C to 150°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *The temperature grade is identified by a label on the shipping container.
Consult LTC Marketing for information on nonstandard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
SHDN Voltage ............................................0.3V to 40V
SYNC Voltage ............................................ 0.3V to 5.5V
Operating Junction Temperature Range
LT8580E (Notes 2, 5) .........................40°C to 125°C
LT8580I (Notes 2, 5) ..........................40°C to 125°C
LT8580H (Notes 2, 5) ........................40°C to 150°C
Storage Temperature Range ..................6C to 150°C
LT8580
3
8580f
For more information www.linear.com/LT8580
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: The LT8580E is guaranteed to meet performance specifications
from 0°C to 125°C junction temperature. Specifications over the –40°C
to 125°C operating junction temperature range are assured by design,
characterization and correlation with statistical process controls. The
LT8580I is guaranteed over the full –40°C to 125°C operating junction
temperature range. The LT8580H is guaranteed over the full –40°C to
150°C operating junction temperature range. Operating lifetime is derated
at junction temperatures greater than 125°C.
elecTrical characTerisTics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VIN = 5V, VSHDN = VIN unless otherwise noted. (Note 2)
PARAMETER CONDITIONS MIN TYP MAX UNITS
Operating Voltage Range LT8580E, LT8580I
LT8580H
l
l
2.55
2.9 40
40 V
V
Positive Feedback Voltage l1.185 1.204 1.220 V
Negative Feedback Voltage l–3 3 12 mV
Positive FBX Pin Bias Current VFBX = Positive Feedback Voltage, Current Into Pin l81 83.3 85 µA
Negative FBX Pin Bias Current VFBX = Negative Feedback Voltage, Current Out of Pin l81 83.3 86 µA
Error Amplifier Transconductance 200 µmhos
Error Amplifier Voltage Gain 60 V/V
Quiescent Current VSHDN = 2.5V, Not Switching 1.2 1.7 mA
Quiescent Current in Shutdown VSHDN = 0V 0 1 µA
Reference Line Regulation 2.5V ≤ VIN ≤ 40V 0.01 0.05 %/V
Switching Frequency, fOSC RT = 56.2k
RT = 422k
l
l
1.23
165 1.5
200 1.77
235 MHz
kHz
Switching Frequency in Foldback Compared to Normal fOSC 1/6 Ratio
Switching Frequency Set Range SYNCing or Free Running l200 1500 kHz
SYNC High Level for Synchronization l1.3 V
SYNC Low Level for Synchronization l0.4 V
SYNC Clock Pulse Duty Cycle VSYNC = 0V to 2V 35 65 %
Recommended Minimum SYNC Ratio fSYNC/fOSC 3/4
Minimum Off-Time 100 ns
Minimum On-Time 350 ns
Switch Current Limit Minimum Duty Cycle (Note 3)
Maximum Duty Cycle (Notes 3, 4), fOSC = 1.5MHz
Maximum Duty Cycle (Notes 3, 4), fOSC = 200kHz
l
l
l
1.2
0.6
0.4
1.5
1
0.8
1.8
1.5
1.4
A
A
A
Switch VCESAT ISW = 0.75A 400 mV
Switch Leakage Current VSW = 5V 0.01 1 µA
Soft-Start Charging Current VSS = 0.5V l4 6 8 µA
SHDN Minimum Input
Voltage High Active Mode, SHDN Rising
Active Mode, SHDN Falling
l
l
1.23
1.21 1.31
1.27 1.4
1.33 V
V
SHDN Input Voltage Low Shutdown Mode l0.3 V
SHDN Pin Bias Current VSHDN = 3V
VSHDN = 1.3V
VSHDN = 0V
944
12
0
56
15
0.1
µA
µA
µA
SHDN Hysteresis 40 mV
Note 3: Current limit guaranteed by design and/or correlation to static test.
Note 4: Current limit measured at equivalent of listed switching frequency.
Note 5: This IC includes overtemperature protection that is intended
to protect the device during momentary overload conditions. Junction
temperature will exceed 150°C when overtemperature protection is active.
Continuous operation above the specified maximum operating junction
temperature may impair device reliability.
LT8580
4
8580f
For more information www.linear.com/LT8580
Typical perForMance characTerisTics
Switch Current Limit vs Duty Cycle Switch Saturation Voltage Commanded Switch Current vs SS
Switch Current Limit
vs Temperature
Positive and Negative Output
Voltage Regulation
Positive and Negative FBX Current
at Output Voltage Regulation Oscillator Frequency
TA = 25°C, unless otherwise specified
DUTY CYCLE (%)
10
0
SWITCH CURRENT LIMIT (A)
0.50
0.75
0.25
1.00
1.25
1.50
1.75
30 50 70 90
8580 G01
2.00
20 40 60 80
SWITCH CURRENT (A)
0
SATURATION VOLTAGE (mV)
400
500
600
1.5
8580 G02
300
200
00.50.25 0.75 11.25
100
700
SS VOLTAGE (V)
0
0
SWITCH CURRENT (A)
0.5
1.0
1.5
2.0
0.2 0.4 0.6 0.8
8580 G03
1 1.2
TEMPERATURE (°C)
–50 –25
0
SWITCH CURRENT LIMIT (A)
0.5
1.0
1.5
2.0
0 5025 125 15010075
8580 G04
TEMPERATURE (°C)
–50 –25
1.170
POSITIVE FBX VOLTAGE (V)
NEGATIVE FBX VOLTAGE (mV)
1.200
1.220
050 75
8580 G05
1.175
1.180
1.185
1.190
1.195
1.215
1.210
1.205
–20
15
30
–10
–15
–5
0
5
10
25
20
25 100 150125
TEMPERATURE (°C)
–50 –25
80
POSITIVE FBX CURRENT INTO PIN (µA)
NEGATIVE FBX CURRENT OUT OF PIN (µA)
86
050 75
8580 G06
81
82
83
84
85
80
86
81
82
83
84
85
25 100 150125
TEMPERATURE (°C)
–50 –25
FREQUENCY (MHz)
0.8
1.0
1.2
1.4
8580 G07
0.6
0.4
005025 75 100 125 150
0.2
1.8
1.6 RT = 56.2k
RT = 422k
LT8580
5
8580f
For more information www.linear.com/LT8580
Typical perForMance characTerisTics
SHDN Pin Current
SHDN Pin Current Active/Lockout Threshold
TA = 25°C, unless otherwise specified
Oscillator Frequency During
Soft-Start Internal UVLO
FBX VOLTAGE (V)
0
0
NORMALIZED OSCILLATOR FREQUENCY (F/FNOM)
1/4
1/2
1/3
1/6
1/5
1
0.2 0.4
INVERTING
CONFIGURATIONS NONINVERTING
CONFIGURATIONS
0.6 0.8
8580 G08
1 1.2
TEMPERATURE (°C)
–50 –25
2.1
VIN VOLTAGE (V)
2.2
2.7
2.4
2.3
0 5025 75
8580 G09
2.5
2.6
125100 150
SHDN VOLTAGE (V)
0
0
SHDN PIN CURRENT (µA)
5
10
15
20
25
30
0.50.25 1 1.50.75 1.25 1.75 2
8580 G10
125°C
25°C
–40°C
SHDN VOLTAGE (V)
0
SHDN PIN CURRENT (µA)
200
250
300
350
400
15 25
8580 G11
150
100
5 10 20 30 35 40
50
0
125°C
25°C
–40°C
TEMPERATURE (°C)
–50 –25
1.20
SHDN VOLTAGE (V)
1.22
1.26
1.28
1.30
1.40
1.34
0 50 75
8580 G12
1.24
1.36
1.38
1.32
100 125 150
SHDN RISING
SHDN FALLING
25
LT8580
6
8580f
For more information www.linear.com/LT8580
pin FuncTions
FBX (Pin 1): Positive and Negative Feedback Pin. For a
noninverting or inverting converter, tie a resistor from
the FBX pin to VOUT according to the following equations:
RFBX =
V
OUT
1.204V
( )
83.3µA ; Noninverting Converter
RFBX =VOUT + 3mV
( )
83.3µA ; InvertingConverter
VC (Pin 2): Error Amplifier Output Pin. Tie external com-
pensation network to this pin.
VIN (Pin 3): Input Supply Pin. Must be locally bypassed.
SW (Pin 4): Switch Pin. This is the collector of the internal
NPN Power switch. Minimize the metal trace area connec-
ted to this pin to minimize EMI.
SHDN (Pin 5): Shutdown Pin. In conjunction with the
UVLO (undervoltage lockout) circuit, this pin is used
to enable/disable the chip and restart the soft-start
sequence. Drive below 1.21V to disable the chip. Drive
above 1.40V to activate the chip and restart the soft-start
sequence. Do not float this pin.
RT (Pin 6): Timing Resistor Pin. Adjusts the switching
frequency. Place a resistor from this pin to ground to set
the frequency to a fixed free running level. Do not float
this pin.
SS (Pin 7): Soft-Start Pin. Place a soft-start capacitor here.
Upon start-up, the SS pin will be charged by a (nominally)
280k resistor to about 2.1V.
SYNC (Pin 8): To synchronize the switching frequency to
an outside clock, simply drive this pin with a clock. The
high voltage level of the clock needs to exceed 1.3V, and
the low level should be less 0.4V. Drive this pin to less
than 0.4V to revert to the internal free-running clock. See
the Applications Information section for more information.
GND (Exposed Pad Pin 9): Ground. Exposed pad must
be soldered directly to local ground plane.
LT8580
7
8580f
For more information www.linear.com/LT8580
block DiagraM
+
+
+
+
+
7
5
31.204V
REFERENCE
ADJUSTABLE
OSCILLATOR
FREQUENCY
FOLDBACK
SLOPE
COMPENSATION
COMPARATOR
DISCHARGE
DETECT
SS VC
280k
Q2
SR2
R
S
14.5k
14.5k
QSR1
A3
A4
A1
A2
SYNC
÷N
RT
SHDN
FBX
1.3V
VC
C1
SW
0.02Ω
GND
RT
RFBX
DRIVER
L1
D1
ILIMIT
VIN
VOUT
CSS CCCIN
RCVIN
SOFT-
START
SYNC
BLOCK
UVLO
RSQ
6
2
1
8580 BD
8
4
Q1
9
50k
LT8580
8
8580f
For more information www.linear.com/LT8580
operaTion
Figure 1. SEPIC Topology Allows for the Input to Span
the Output Voltage. Coupled or Uncoupled Inductors
Can Be Used. Follow Noted Phasing if Coupled
Figure 2. Dual Inductor Inverting Topology Results in
Low Output Ripple. Coupled or Uncoupled Inductors
Can Be Used. Follow Noted Phasing if Coupled
D1
SHUTDOWN
L2
C3
L1
R1
VIN > VOUT
OR
VIN = VOUT
OR
VIN < VOUT
V
OUT
VIN SW
8580 F01
LT8580
RT
RC
C2
SHDN
GND
FBX
VC
SYNC SS
RT
CC
CSS
C1
+
+
D1
SHUTDOWN
C3
L1
R1
VIN VOUT
VIN SW
8580 F02
LT8580
C2
SHDN
GND
FBX
VC
SYNC SS
RT
CSS
C1
L2
+
+
RT
RC
CC
The LT8580 uses a constant-frequency, current mode con-
trol scheme to provide excellent line and load regulation.
Refer to the Block Diagram for the following description
of the part’s operation. At the start of each oscillator cycle,
the SR latch (SR1) is set, which turns on the power switch,
Q1. The switch current flows through the internal current
sense resistor, generating a voltage proportional to the
switch current. This voltage (amplified by A4) is added
to a stabilizing ramp and the resulting sum is fed into the
positive terminal of the PWM comparator A3. When this
voltage exceeds the level at the negative input of A3, the
SR latch is reset, turning off the power switch. The level
at the negative input of A3 (VC pin) is set by the error
amplifier A1 (or A2) and is simply an amplified version of
the difference between the feedback voltage (FBX pin) and
the reference voltage (1.204V or 3mV, depending on the
configuration). In this manner, the error amplifier sets the
correct peak current level to keep the output in regulation.
The LT8580 has an FBX pin architecture that can be used
for either noninverting or inverting configurations. When
configured as a noninverting converter, the FBX pin is
pulled up to the internal bias voltage of 1.204V by the
RFBX resistor connected from VOUT to FBX. Amplifier A2
becomes inactive and amplifier A1 performs the invert-
ing amplification from FBX to VC. When the LT8580 is in
an inverting configuration, the FBX pin is pulled down to
3mV by the RFBX resistor connected from VOUT to FBX.
Amplifier A1 becomes inactive and amplifier A2 performs
the noninverting amplification from FBX to VC.
SEPIC Topology
As shown in Figure 1, the LT8580 can be configured as
a SEPIC (single-ended primary inductance converter).
This topology allows for the input to be higher, equal, or
lower than the desired output voltage. Output disconnect
is inherently built into the SEPIC topology, meaning no DC
path exists between the input and output. This is useful
for applications requiring the output to be disconnected
from the input source when the circuit is in shutdown.
Inverting Topology
The LT8580 can also work in a dual inductor inverting
topology, as shown in Figure 2. The part’s unique feedback
pin allows for the inverting topology to be built by simply
changing the connection of external components. This
solution results in very low output voltage ripple due to
the inductor L2 in series with the output. Abrupt changes
in output capacitor current are eliminated because the
output inductor delivers current to the output during both
the off-time and the on-time of the LT8580 switch.
LT8580
9
8580f
For more information www.linear.com/LT8580
Start-Up Operation
Several functions are provided to enable a very clean
start-up for the LT8580.
• First, the SHDN pin voltage is monitored by an internal
voltage reference to give a precise turn-on voltage level.
An external resistor (or resistor divider) can be connected
from the input power supply to the SHDN pin to provide
a user-programmable undervoltage lockout function.
• Second, the soft-start circuitry provides for a gradual
ramp-up of the switch current. When the part is brought
out of shutdown, the external SS capacitor is first
discharged (providing protection against SHDN pin
glitches and slow ramping), then an integrated 280k
resistor pulls the SS pin up to ~2.1V. By connecting an
external capacitor to the SS pin, the voltage ramp rate
on the pin can be set. Typical values for the soft-start
capacitor range from 100nF to 1µF.
• Finally, the frequency foldback circuit reduces the switch-
ing frequency when the FBX pin is in a nominal range
of 300mV to 920mV. This feature reduces the minimum
duty cycle that the part can achieve thus allowing better
control of the switch current during start-up. When the
FBX voltage is pulled outside of this range, the switching
frequency returns to normal.
Current Limit and Thermal Shutdown Operation
The LT8580 has a current limit circuit not shown in the
Block Diagram. The switch current is constantly monitored
and not allowed to exceed the maximum switch current at
a given duty cycle (see the Electrical Characteristics table).
If the switch current reaches this value, the SR latch (SR1)
is reset regardless of the state of the comparator (A1/
A2). Also, not shown in the Block Diagram is the thermal
shutdown circuit. If the temperature of the part exceeds
approximately 165°C, the SR2 latch is set regardless of the
state of the amplifier (A1/A2). When the part temperature
falls below approximately 160°C, a full soft-start cycle will
then be initiated. The current limit and thermal shutdown
circuits protect the power switch as well as the external
components connected to the LT8580.
operaTion
LT8580
10
8580f
For more information www.linear.com/LT8580
applicaTions inForMaTion
Inductor Selection
General Guidelines
: The high frequency operation of the
LT8580 allows for the use of small surface mount inductors.
For high efficiency, choose inductors with high frequency
core material, such as ferrite, to reduce core losses. To
improve efficiency, choose inductors with more volume
for a given inductance. The inductor should have low
DCR (copper wire resistance) to reduce I2R losses, and
must be able to handle the peak inductor current without
saturating. Note that in some applications, the current
handling requirements of the inductor can be lower, such
as in the SEPIC topology, where each inductor only carries
a fraction of the total switch current. Multilayer or chip
inductors usually do not have enough core area to sup-
port peak inductor currents in the 1A to 2A range. To
minimize radiated noise, use a toroidal or shielded induc-
tor. Note that the inductance of shielded types will drop
more as current increases, and will saturate more easily.
See Table 1 for a list of inductor manufacturers. Thorough
lab evaluation is recommended to verify that the following
guidelines properly suit the final application.
Table 1. Inductor Manufacturers
Coilcraft XAL5050, MSD7342, MSS7341 and
LPS4018 Series www.coilcraft.com
Coiltronics DR, DRQ, LD and CD Series www.coiltronics.com
Sumida CDRH8D58/LD, CDRH64B, and
CDRH70D430MN Series www.sumida.com
Würth WE-PD, WE-DD, WE-TPC,
WE-LHMI and WE-LQS Series www.we-online.com
Minimum Inductance
: Although there can be a trade-off
with efficiency, it is often desirable to minimize board
space by choosing smaller inductors. When choosing
an inductor, there are two conditions that limit the mini-
mum inductance: (1) providing adequate load current,
and (2) avoiding subharmonic oscillation. Choose an
inductance that is high enough to meet both of these
requirements.
Adequate Load Current
: Small value inductors result in
increased ripple currents and thus, due to the limited peak
switch current, decrease the average current that can be
Setting Output Voltage
The output voltage is set by connecting a resistor (RFBX)
from VOUT to the FBX pin. RFBX is determined from the
following equation:
RFBX =
|V
OUT
V
FBX
|
83.3µA
where VFBX is 1.204V (typical) for noninverting topologies
(i.e., boost and SEPIC regulators) and 3mV (typical) for
inverting topologies (see the Electrical Characteristics).
Power Switch Duty Cycle
In order to maintain loop stability and deliver adequate
current to the load, the power NPN (Q1 in the Block Dia-
gram) cannot remainon” for 100% of each clock cycle.
The maximum allowable duty cycle is given by:
DCMAX =
(T
P
MinOff Time)
T
P
100%
where TP is the clock period and Min Off Time (found in
the Electrical Characteristics) is typically 100ns.
The application should be designed so that the operating
duty cycle does not exceed DCMAX.
Duty cycle equations for several common topologies are
given below, where VD is the diode forward voltage drop
and VCESAT is typically 400mV at 0.75A.
For the boost topology:
DC
OUT
IN +
D
V
+V
V
For the SEPIC or dual inductor inverting topology (see
Figure 1 and Figure 2):
DC
V
D+
|V
OUT
|
V
IN
+|V
OUT
|+V
D
V
CESAT
The LT8580 can be used in configurations where the duty
cycle is higher than DCMAX, but it must be operated in the
discontinuous conduction mode so that the effective duty
cycle is reduced.
LT8580
11
8580f
For more information www.linear.com/LT8580
applicaTions inForMaTion
provided to a load (IOUT). In order to provide adequate
load current, L should be at least:
LBOOST >
DC V
IN
2(f) ILIM |VOUT|IOUT
VIN h
for boost, topologies, or:
LDUAL >
DC V
IN
2(f) ILIMVOUT IOUT
VIN hIOUT
for the SEPIC and inverting topologies.
where:
LBOOST = L1 for boost topologies (see Figure 15)
LDUAL = L1 = L2 for coupled dual inductor topologies
(see Figure 16 and Figure 17)
LDUAL = L1||L2 for uncoupled dual inductor topologies
(see Figure 16 and Figure 17)
DC = switch duty cycle (see previous section)
ILIM = switch current limit, typically about 1.2A at 50%
duty cycle (see the Typical Performance Characteristics
section).
h = power conversion efficiency (typically 85% for boost
and 83% for dual inductor topologies at high currents).
f = switching frequency
IOUT = maximum load current
Negative values of L indicate that the output load current
IOUT exceeds the switch current limit capability of the
LT8580.
Avoiding Subharmonic Oscillations
: The LT8580’s internal
slope compensation circuit can prevent subharmonic oscil-
lations that can occur when the duty cycle is greater than
50%, provided that the inductance exceeds a minimum
value. In applications that operate with duty cycles greater
than 50%, the inductance must be at least:
LMIN >
V
IN
1.25 (DC300nS f) f
2DC
1
1DC
LMIN = L1 for boost topologies (see Figure 15)
LMIN = L1 = L2 for coupled dual inductor topologies
(see Figure 16 and Figure 17)
LMIN = L1||L2 for uncoupled dual inductor topologies
(see Figure 16 and Figure 17)
Maximum Inductance
: Excessive inductance can reduce
current ripple to levels that are difficult for the current com-
parator (A3 in the Block Diagram) to cleanly discriminate,
thus causing duty cycle jitter and/or poor regulation. The
maximum inductance can be calculated by:
LMAX =
V
IN
V
CESAT
I
MIN-RIPPLE
DC
f
where
LMIN = L1 for boost topologies (see Figure 15)
LMIN = L1 = L2 for coupled dual inductor topologies
(see Figure 16 and Figure 17)
LMIN = L1||L2 for uncoupled dual inductor topologies
(see Figure 16 and Figure 17)
IMIN(RIPPLE) = typically 80mA
Current Rating
: Finally, the inductor(s) must have a rating
greater than its peak operating current to prevent inductor
saturation resulting in efficiency loss. In steady state, the
peak input inductor current (continuous conduction mode
only) is given by:
IL1-PEAK =
|V
OUT
I
OUT
|
V
IN
h+
V
IN
DC
2L1f
for the boost, uncoupled inductor SEPIC and uncoupled
inductor inverting topologies.
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For uncoupled dual inductor topologies, the peak output
inductor current is given by:
IL2-PEAK =IOUT +
V
OUT
1
DC
( )
2L2 f
For the coupled inductor topologies:
IL2-PEAK =IOUT 1+VOUT
hV
IN
+VIN DC
2Lf
Note: Inductor current can be higher during load transients.
It can also be higher during start-up if inadequate soft-start
capacitance is used.
Capacitor Selection
Low ESR (equivalent series resistance) capacitors should
be used at the output to minimize the output ripple voltage.
Multilayer ceramic capacitors are an excellent choice, as
they have an extremely low ESR and are available in very
small packages. X5R or X7R dielectrics are preferred, as
these materials retain their capacitance over wider voltage
and temperature ranges. A 0.47µF to 10µF output capacitor
is sufficient for most applications. Always use a capacitor
with a sufficient voltage rating. Many ceramic capacitors,
particularly 0805 or 0603 case sizes, have greatly reduced
capacitance at the desired output voltage. Solid tantalum
or OS-CON capacitors can be used, but they will occupy
more board area than a ceramic and will have a higher
ESR with greater output ripple.
Ceramic capacitors also make a good choice for the input
decoupling capacitor, which should be placed as closely
as possible to the VIN pin of the LT8580 as well as to the
inductor connected to the input of the power path. If it is
not possible to optimally place a single input capacitor,
then use one at the VIN pin of the chip (CVIN) and one at
the input of the power path (CPWR). See equations in
Table 4, Table 5 and Table 6 for sizing information. AF
to 2.2µF input capacitor is sufficient for most applications.
Table 2 shows a list of several ceramic capacitor manu-
facturers. Consult the manufacturers for detailed informa-
tion on their entire selection of ceramic parts.
Table 2. Ceramic Capacitor Manufacturers
Kemet www.kemet.com
Murata www.murata.com
Taiyo Yuden www.t-yuden.com
TDK www.tdk.com
Compensation—Adjustment
To compensate the feedback loop of the LT8580, a series
resistor-capacitor network in parallel with a single capacitor
should be connected from the VC pin to GND. For most
applications, the series capacitor should be in the range
of 470pF to 2.2nF with 1nF being a good starting value.
The parallel capacitor should range in value from 10pF to
100pF with 47pF a good starting value. The compensation
resistor, RC, is usually in the range of 5k to 50k. A good
technique to compensate a new application is to use a
100kΩ potentiometer in place of series resistor RC. With
the series capacitor and parallel capacitor at 1nF and 47pF
respectively, adjust the potentiometer while observing
the transient response and the optimum value for RC can
be found. Figure 3 (3a to 3c) illustrates this process for
the circuit of Figure 4 with a load current stepped be-
tween 60mA and 160mA. Figure 3a shows the transient
response with RC equal to 2k. The phase margin is poor,
as evidenced by the excessive ringing in the output
voltage and inductor current. In Figure 3b, the value of
RC is increased to 3k, which results in a more damped
response. Figure 3c shows the results when RC is increased
further to 6k. The transient response is nicely damped and
the compensation procedure is complete.
Compensation—Theory
Like all other current mode switching regulators, the
LT8580 needs to be compensated for stable and efficient
operation. Two feedback loops are used in the LT8580—
a fast current loop which does not require compensation,
and a slower voltage loop which does. Standard bode plot
analysis can be used to understand and adjust the voltage
feedback loop.
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(3a) Transient Response Shows Excessive Ringing
Figure 3. Transient Response
(3b) Transient Response Is Better
(3c) Transient Response Is Well Damped
Figure 4. 1.5MHz, 5V to 12V Boost Converter
VOUT
500mV/DIV
AC-COUPLED
IL1
200mA/DIV
ISTEP
100mA/DIV
100µs/DIV 8580 F03a
VOUT
500mV/DIV
AC-COUPLED
IL1
200mA/DIV
ISTEP
100mA/DIV
100µs/DIV
8580 F03b
VOUT
500mV/DIV
AC-COUPLED
IL1
200mA/DIV
ISTEP
100mA/DIV
100µs/DIV 8580 F03c
COUT
4.7µF
VOUT
12V
200mA
L1
15µH D1
RFBX
130k
VIN
5V
VIN SW
8580 F04
LT8580
10k
RC
6.04k
RT
56.2k
SHDN
GND
FBX
VCSYNC
SSRT
CC
3.3nF
CF
47pF
CSS
0.22µF
CIN
2.2µF
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As with any feedback loop, identifying the gain and phase
contribution of the various elements in the loop is critical.
Figure 5 shows the key equivalent elements of a boost con-
verter. Because of the fast current control loop, the power
stage of the IC, inductor and diode have been replaced by
a combination of the equivalent transconductance ampli-
fier gmp and the current controlled current source which
converts IVIN to (hVIN/VOUT) •IVIN. gmp acts as a current
source where the peak input current, IVIN, is proportional
to the VC voltage. h is the efficiency of the switching
regulator, and is typically about 85%.
Note that the maximum output currents of gmp and gma are
finite. The limits for gmp are in the Electrical Characteristics
section (switch current limit), and gma is nominally limited
to about +15µA and –17µA.
Figure 5. Boost Converter Equivalent Model
+
+
gma
RCRO
R2
R2
CC: COMPENSATION CAPACITOR
COUT: OUTPUT CAPACITOR
CPL: PHASE LEAD CAPACITOR
CF: HIGH FREQUENCY FILTER CAPACITOR
gma: TRANSCONDUCTANCE AMPLIFIER INSIDE IC
gmp: POWER STAGE TRANSCONDUCTANCE AMPLIFIER
RC: COMPENSATION RESISTOR
RL: OUTPUT RESISTANCE DEFINED AS VOUT DIVIDED BY ILOAD(MAX)
RO: OUTPUT RESISTANCE OF gma
R1, R2: FEEDBACK RESISTOR DIVIDER NETWORK
RESR: OUTPUT CAPACITOR ESR
η: CONVERTER EFFICIENCY (~85% AT HIGHER CURRENTS)
8580 F05
R1
FBX
COUT
CPL
RL
RESR
VOUT
IVIN
VC
CC
CF
gmp
1.204V
REFERENCE
ηVIN
VOUT
IVIN
From Figure 5, the DC gain, poles and zeros can be cal-
culated as follows:
Output Pole: P1=
2
2πRLCOUT
Error AmpPole: P2 = 1
2πRO+RC
[ ]
CC
Error Amp Zero: Z1= 1
2πRCCC
DC Gain:
(Breaking Loop at FBX Pin)
ADC = AOL(0) = ∂VC
∂VFBX
∂IVIN
∂VC
∂VOUT
∂IVIN
∂VFBX
∂VOUT
=
gma R0
( )
gmp hVIN
VOUT
RL
2
0.5R2
R1+ 0.5R2
ESR Zero: Z2 = 1
2πRESR COUT
RHP Zero: Z3 = VIN
2RL
4πVOUT
2L
HighFrequency Pole: P3 > fS
3
Phase Lead Zero: Z4 = 1
2πR1CPL
Phase LeadPole: P4 = 1
2π
R1R2
2
R1+ R2
2
CPL
Error Amp Filter Pole:
P5 = 1
2πRCRO
R
C
+R
O
CF
,CF<CC
10
The current mode zero (Z3) is a right-half plane zero
which can be an issue in feedback control design, but is
manageable with proper external component selection.
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Using the circuit in Figure 4 as an example, Table 3 shows
the parameters used to generate the bode plot shown in
Figure 6.
In Figure 6, the phase is –125° when the gain reaches 0dB
giving a phase margin of 55°. The crossover frequency is
20kHz, which is more than three times lower than the fre-
quency of the RHP zero to achieve adequate phase margin.
Diode Selection
Schottky diodes, with their low forward-voltage drops and
fast switching speeds, are recommended for use with the
LT8580. For applications where VR (see Tables 4, 5 and
6) < 40V, the Diodes, Inc. SBR1V40LP is a good choice.
Where VR > 40V, the Diodes Inc. DFLS1100 works well.
These diodes are rated to handle an average forward
current of 1A.
Oscillator
The operating frequency of the LT8580 can be set by the
internal free-running oscillator. When the SYNC pin is
driven low (< 0.4V), the frequency of operation is set by a
resistor from RT to ground. An internally trimmed timing
capacitor resides inside the IC. The oscillator frequency
is calculated using the following formula:
fOSC =
85.5
(R
T
+1)
where fOSC is in MHz and RT is in kΩ. Conversely, RT
(in kΩ) can be calculated from the desired frequency
(in MHz) using:
RT=
85.5
f
OSC
1
Clock Synchronization
The operating frequency of the LT8580 can be synchro-
nized to an external clock source. To synchronize to the
external source, simply provide a digital clock signal into
the SYNC pin. The LT8580 will operate at the SYNC clock
frequency. The LT8580 will revert to the internal free-
running oscillator clock after SYNC is driven low for a few
free-running clock periods.
Figure 6. Bode Plot for Example Boost Converter
FREQUENCY (Hz)
10
60
GAIN (dB)
PHASE (DEG)
80
100
120
100 1k 10k 100k 1M
8580 F06
40
20
0
–20
140
–180
–135
–90
–45
–225
–270
–315
–360
0
55° AT
20kHz
PHASE
GAIN
Table 3. Bode Plot Parameters
PARAMETER VALUE UNITS COMMENT
RL40 WApplication Specific
COUT 4.7 µF Application Specific
RESR 10 mWApplication Specific
RO305 kWNot Adjustable
CC3300 pF Adjustable
CF47 pF Optional/Adjustable
CPL 0 pF Optional/Adjustable
RC6.04 kWAdjustable
R1 130 kWAdjustable
R2 14.6 kWNot Adjustable
VOUT 12 V Application Specific
VIN 5 V Application Specific
gma 230 µmho Not Adjustable
gmp 7 mho Not Adjustable
L 15 µH Application Specific
fS1.5 MHz Adjustable
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Driving SYNC high for an extended period of time effec-
tively stops the operating clock and prevents latch SR1
from becoming set (see the Block Diagram). As a result,
the switching operation of the LT8580 will stop.
The duty cycle of the SYNC signal must be between 35%
and 65% for proper operation. Also, the frequency of the
SYNC signal must meet the following two criteria:
(1) SYNC may not toggle outside the frequency range of
200kHz to 1.5MHz unless it is stopped low to enable
the free-running oscillator.
(2) The SYNC frequency can always be higher than the
free-running oscillator frequency, fOSC, but should not
be less than 25% below fOSC.
Operating Frequency Selection
There are several considerations in selecting the operat-
ing frequency of the converter. The first is staying clear
of sensitive frequency bands, which cannot tolerate any
spectral noise. For example, in products incorporating RF
communications, the 455kHz IF frequency is sensitive to
any noise, therefore switching above 600kHz is desired.
Some communications have sensitivity to 1.1MHz, and in
that case, a 1.5MHz switching converter frequency may be
employed. The second consideration is the physical size
of the converter. As the operating frequency goes up, the
inductor and filter capacitors go down in value and size.
The trade-off is efficiency, since the switching losses due
to NPN base charge (see Thermal Calculations), Schottky
diode charge, and other capacitive loss terms increase
proportionally with frequency.
Soft-Start
The LT8580 contains a soft-start circuit to limit peak switch
currents during start-up. High start-up current is inherent
in switching regulators in general since the feedback loop
is saturated due to VOUT being far from its final value. The
regulator tries to charge the output capacitor as quickly as
possible, which results in large peak currents.
The start-up current can be limited by connecting an
external capacitor (typically 100nF to 1µF) to the SS pin.
This capacitor is slowly charged to ~2.1V by an internal
280k resistor once the part is activated. SS pin voltages
below ~1.1V reduce the internal current limit. Thus, the
gradual ramping of the SS voltage also gradually increases
the current limit as the capacitor charges. This, in turn,
allows the output capacitor to charge gradually toward its
final value while limiting the start-up current.
In the event of a commanded shutdown or lockout (SHDN
pin), internal undervoltage lockout (UVLO) or a thermal
lockout, the soft-start capacitor is automatically discharged
to ~200mV before charging resumes, thus assuring that
the soft-start occurs after every reactivation of the chip.
Shutdown
The SHDN pin is used to enable or disable the chip. For
most applications, SHDN can be driven by a digital logic
source. Voltages above 1.4V enable normal active op-
eration. Voltages below 300mV will shutdown the chip,
resulting in extremely low quiescent current.
While the SHDN voltage transitions through the lockout
voltage range (0.3V to 1.21V) the power switch is disabled
and the SR2 latch is set (see the Block Diagram). This
causes the soft-start capacitor to begin discharging, which
continues until the capacitor is discharged and active op-
eration is enabled. Although the power switch is disabled,
SHDN voltages in the lockout range do not necessarily
reduce quiescent current until the SHDN voltage is near
or below the shutdown threshold.
Also note that SHDN can be driven above VIN or VOUT as
long as the SHDN voltage is limited to less than 40V.
Figure 7. Chip States vs SHDN Voltage
(HYSTERESIS AND TOLERANCE)
SHUTDOWN
(LOW QUIESCENT CURRENT)
ACTIVE
(NORMAL OPERATION)
LOCKOUT
(POWER SWITCH OFF,
SS CAPACITOR DISCHARGED)
1.21V
0.0V
1.40V
0.3V
8580 F07
SHDN (V)
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Configurable Undervoltage Lockout
Figure 8 shows how to configure an undervoltage lock-
out (UVLO) for the LT8580. Typically, UVLO is used in
situations where the input supply is current-limited, has
a relatively high source resistance, or ramps up/down
slowly. A switching regulator draws constant power from
the source, so source current increases as source voltage
drops. This looks like a negative resistance load to the
source and can cause the source to current-limit or latch
low under low source voltage conditions. UVLO prevents
the regulator from operating at source voltages where
these problems might occur.
The shutdown pin comparator has voltage hysteresis with
typical thresholds of 1.31V (rising) and 1.27V (falling). Re-
sistor RUVLO2 is optional. RUVLO2 can be included to reduce
the overall UVLO voltage variation caused by variations
in SHDN pin current (see the Electrical Characteristics).
A good choice for RUVLO2 is 10k ±1%. After choosing a
value for RUVLO2, RUVLO1 can be determined from either
of the following:
RUVLO1 =VIN
+
1.31V
1.31V
RUVLO2
+12µA
or
RUVLO1 =VIN1.27V
1.27V
RUVLO2
+12µA
where VIN+ and VIN are the VIN voltages when rising or
falling, respectively.
Figure 8. Configurable UVLO
For example, to disable the LT8580 for VIN voltages below
3.5V using the single resistor configuration, choose:
RUVLO1 =
3.5V
1.27V
1.27V
+12µA
= 187k
To activate the LT8580 for VIN voltages greater than
4.5V using the double resistor configuration, choose
RUVLO2 = 10k and:
RUVLO1 =
4.5V
1.31V
1.31V
10k
+12µA
= 22.1k
Internal Undervoltage Lockout
The LT8580 monitors the VIN supply voltage in case VIN
drops below a minimum operating level (typically about
2.35V). When VIN is detected low, the power switch is
deactivated, and while sufficient VIN voltage persists, the
soft-start capacitor is discharged. After VIN is detected
high, the power switch will be reactivated and the soft-
start capacitor will begin charging.
Thermal Considerations
For the LT8580 to deliver its full output power, it is impera-
tive that a good thermal path be provided to dissipate the
heat generated within the package. This is accomplished
by taking advantage of the thermal pad on the underside of
the IC. It is recommended that multiple vias in the printed
circuit board be used to conduct heat away from the IC
and into a copper plane with as much area as possible.
RUVLO2
(OPTIONAL)
1.3V
RUVLO1
8580 F08
VIN
VIN
ACTIVE/
LOCKOUT
GND
12µA
AT 1.3V
+
SHDN
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Thermal Lockout
If the die temperature reaches approximately 165°C, the
part will go into thermal lockout, the power switch will be
turned off and the soft-start capacitor will be discharged.
The part will be enabled again when the die temperature
has dropped by ~5°C (nominal).
Thermal Calculations
Power dissipation in the LT8580 chip comes from four
primary sources: switch I2R loss, NPN base drive (AC),
NPN base drive (DC), and additional input current. The
following formulas can be used to approximate the power
losses. These formulas assume continuous mode opera-
tion, so they should not be used for calculating efficiency
in discontinuous mode or at light load currents.
AverageInput Current: IIN =
V
OUT
I
OUT
VIN h
Switch I2R Loss: PSW =(DC)(IIN)2(RSW )
BaseDriveLoss(AC): PBAC = 20ns(IIN)(VOUT )(f)
BaseDriveLoss(DC): PBDC =(VIN)(IIN)(DC)
40
Input Power Loss: P
INP
= 6mA (V
IN
)
where:
RSW = switch resistance (typically 530mΩ at 0.75A)
DC = duty cycle (see the Power Switch Duty Cycle sec-
tion for formulas)
h = power conversion efficiency (typically 85% at high
currents)
Example: boost configuration, VIN = 5V, VOUT = 12V,
IOUT = 0.2A, f = 1.25MHz, VD = 0.5V:
IIN = 0.56A
DC = 62.0%
PSW = 105mW
PBAC = 169mW
PBDC = 44mW
PINP = 30mW
Total LT8580 power dissipation (PTOT) = 348mW
Thermal resistance for the LT8580 is influenced by the pres-
ence of internal, topside or backside planes. To calculate
die temperature, use the appropriate thermal resistance
number and add in worst-case ambient temperature:
TJ = TA + θJA•PTOT
where TJ = junction temperature, TA = ambient temperature,
and θJA is the thermal resistance from the silicon junction
to the ambient air.
The published θJA value is 43°C/W for the 3mm × 3mm
DFN package and 35°C/W to 40°C/W for the MSOP ex-
posed pad package. In practice, lower θJA values can be
obtained if the board layout uses ground as a heat sink.
For instance, thermal resistances of 34.7°C/W for the
DFN package and 22.5°C/W for the MSOP package were
obtained on a board designed with large ground planes.
VIN Ramp Rate
While initially powering a switching converter application,
the VIN ramp rate should be limited. High VIN ramp rates can
cause excessive inrush currents in the passive components
of the converter. This can lead to current and/or voltage
overstress and may damage the passive components or
the chip. Ramp rates less than 500mV/µs, depending on
component parameters, will generally prevent these issues.
Also, be careful to avoid hot-plugging. Hot-plugging occurs
when an active voltage supply isinstantly” connected or
switched to the input of the converter. Hot-plugging results
in very fast input ramp rates and is not recommended.
Finally, for more information, refer to Linear application
note AN88, which discusses voltage overstress that can
occur when an inductive source impedance is hot-plugged
to an input pin bypassed by ceramic capacitors.
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the board reduces die temperature and increases the power
capability of the LT8580. Provide as much copper area as
possible around this pad. Adding multiple feedthroughs
around the pad to the ground plane will also help. Figure 10
and Figure 11 show the recommended component place-
ment for the boost and SEPIC configurations, respectively.
Layout Hints for Inverting Topology
Figure 12 shows recommended component placement for
the dual inductor inverting topology. Input bypass capaci-
tor, C1, should be placed close to the LT8580, as shown.
The load should connect directly to the output capacitor,
C2, for best load regulation. The local ground may be tied
into the system ground plane at the C3 ground terminal.
The cut ground copper at D1’s cathode is essential to
obtain low noise. This important layout issue arises due
to the chopped nature of the currents flowing in Q1 and
D1. If they are both tied directly to the ground plane before
being combined, switching noise will be introduced into
the ground plane. It is almost impossible to get rid of this
noise, once present in the ground plane. The solution
is to tie D1’s cathode to the ground pin of the LT8580
before the combined currents are dumped in the ground
plane as drawn in Figure 2, Figure 13 and Figure 14. This
single layout technique can virtually eliminate high
frequencyspike” noise, so often present on switching
regulator outputs.
DIFFERENCES FROM LT3580
LT8580 is very similar to LT3580. However, LT8580 does
deviate from LT3580 in a few areas:
• 65V, 1A switch
• 40V VIN and SHDN absolute maximum rating
• FB renamed to FBX
• 5V FBX absolute maximum rating
Figure 9. High Speed “Chopped” Switching
Path for Boost Topology
Layout Hints
As with all high frequency switchers, when considering
layout, care must be taken to achieve optimal electrical,
thermal and noise performance. One will not get adver-
tised performance with a careless layout. For maximum
efficiency, switch rise and fall times are typically in the
10nS to 20nS range. To prevent noise, both radiated and
conducted, the high speed switching current path, shown in
Figure 9, must be kept as short as possible. This is imple-
mented in the suggested layout of a boost configuration in
Figure 10. Shortening this path will also reduce the parasitic
trace inductance. At switch-off, this parasitic inductance
produces a flyback spike across the LT8580 switch. When
operating at higher currents and output voltages, with poor
layout, this spike can generate voltages across the LT8580
that may exceed its absolute maximum rating. A ground
plane should also be used under the switcher circuitry to
prevent interplane coupling and overall noise.
The VC and FBX components should be kept as far away
as practical from the switch node. The ground for these
components should be separated from the switch cur-
rent path. Failure to do so can result in poor stability or
subharmonic oscillation.
Board layout also has a significant effect on thermal re-
sistance. The exposed package ground pad is the copper
plate that runs under the LT8580 die. This is a good thermal
path for heat out of the package. Soldering the pad onto
8580 F09
VOUT
L1
SW
GND
LT8580
D1
C2
C1
VIN
HIGH
FREQUENCY
SWITCHING
PATH
LOAD
LT8580
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Figure 10. Suggested Component Placement for Boost Topology
(Both DFN and MSOP Packages. Not to Scale). Pin 9 (Exposed
Pad) Must Be Soldered Directly to the Local Ground Plane for
Adequate Thermal Performance. Multiple Vias to Additional
Ground Planes Will Improve Thermal Performance
Figure 11. Suggested Component Placement for SEPIC Topology
(Both DFN And MSOP Packages. Not to Scale). Pin 9 (Exposed
Pad) Must Be Soldered Directly to the Local Ground Plane for
Adequate Thermal Performance. Multiple Vias to Additional
Ground Planes Will Improve Thermal Performance
Figure 12. Suggested Component Placement for Inverting Topology (Both DFN and MSOP Packages. Not to Scale).
Note Cut in Ground Copper at Diode’s Cathode. Pin 9 (Exposed Pad) Must be Soldered Directly to Local Ground Plane
for Adequate Thermal Performance. Multiple Vias to Additional Ground Planes Will Improve Thermal Performance
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8580 F11
VOUT
VIN
5
6
7
8
9
4
3
2
1
SW
L1
L2
D1 C3
C2
C1
SHDN
SYNC
GND
VIAS TO GROUND
PLANE REQUIRED
TO IMPROVE
THERMAL
PERFORMANCE
8580 F12
VOUT
VIN
5
6
7
8
9
4
3
2
1
SW
C1
C2
D1
C3
L1
L2
SHDN
SYNC
GND
VIAS TO GROUND
PLANE REQUIRED
TO IMPROVE
THERMAL
PERFORMANCE
8580 F10
VOUT
VIN
C2
L1
C1
D1
5
6
7
8
9
4
3
2
1
SW
SHDN
SYNC
GND
VIAS TO GROUND
PLANE REQUIRED
TO IMPROVE
THERMAL
PERFORMANCE
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Figure 13. Switch-On Phase of an Inverting Converter. L1 and L2 Have Positive dI/dt
Figure 14. Switch-Off Phase of an Inverting Converter. L1 and L2 Currents Have Negative dI/dt
+
+
L1 L2
C2
–(VIN + VOUT)
SW SWX
D1
Q1
8580 F13
C1 C3 RLOAD
–VOUT
VIN
VCESAT
+
+
L1 L2
C2
VIN + VOUT+ VD
SW SWX
D1
Q1
C1 C3 RLOAD
–VOUT
VIN
VD
8580 F14
LT8580
22
8580f
For more information www.linear.com/LT8580
Figure 15. Boost Converter: The Component Values and Voltages
Given Are Typical Values for a 1.5MHz, 5V to 12V Boost
applicaTions inForMaTion
COUT
4.7µF
VOUT
12V
200mA
L1
15µH D1
RFBX
130k
VIN
5V
VIN SW
8580 F15
LT8580
10k
RC
6.04k
RT
56.2k
SHDN
GND
FBX
VCSYNC
SSRT
CC
3.3nF
CF
47pF
CSS
0.22µF
CIN
2.2µF
BOOST CONVERTER COMPONENT SELECTION
The LT8580 can be configured as a boost converter as in
Figure 15. This topology allows for positive output voltages
that are higher than the input voltage. A single feedback
resistor sets the output voltage. For output voltages higher
than 60V, see the Charge Pump Aided Regulators section.
Table 4 is a step-by-step set of equations to calculate com-
ponent values for the LT8580 when operating as a boost
converter. Input parameters are input and output voltage,
and switching frequency (VIN, VOUT and fOSC respectively).
Refer to the Applications Information section for further
information on the design equations presented in Table 4.
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Average Output Current
IRIPPLE = Inductor Ripple Current
Table 4. Boost Design Equations
PARAMETERS/EQUATIONS
Step 1:
Inputs
Pick VIN, VOUT, and fOSC to calculate equations below
Step 2:
DC
DCMAX =
V
OUT
V
IN(MIN) +
0.5V
VOUT +0.5V 0.4 V
DCMIN =VOUT VIN(MAX) +0.5 V
V
OUT +
0.5V 0.4 V
Step 3:
L1
LTYP =(VIN(MIN) 0.4V)DCMAX
fOSC 0.3A
(1)
LMIN =
(V
IN(MIN)
0.4V)(2 DC
MAX
1)
1.25 (DCMAX 300nS fOSC)(1DCMAX )
(2)
LMAX1 =(VIN(MIN) 0.4V)DCMAX
fOSC 0.08A
(3)
LMAX2 =(VIN(MAX) 0.4V)DCMIN
fOSC 0.08A
(4)
•Solve equations 1 to 4 for a range of L values
•The minimum of the L value range is the higher of LTYP and LMIN
•The maximum of the L value range is the lower of LMAX1 and LMAX2.
Step 4:
IRIPPLE
IRIPPLE(MIN) =(VIN(MIN) 0.4V)DCMAX
fOSC L1
IRIPPLE(MAX) =(VIN(MAX) 0.4V)DCMIN
fOSC L
1
Step 5:
IOUT
IOUT(MIN) =1A IRIPPLE(MIN)
2
(1DCMAX )
IOUT(MAX) =1A IRIPPLE(MAX)
2
(1DCMIN)
Step 6:
D1
VR > VOUT; IAVG > IOUT
Step 7:
COUT
COUT IOUT DCMAX
fOSC 0.005 VOUT
Step 8:
CIN
CIN CVIN +CPWR
1A DCMAX
40 fOSC 0.005 VIN(MIN)
+IRIPPLE(MAX)
8fOSC 0.005 VIN(MAX)
•Refer to the Capacitor Selection Section for definition of CVIN and CPWR
Step 9:
RFBX
RFBX =VOUT 1.204V
83.3µA
Step
10:
RT
RT=
85.5
f
OSC
1; fOSC in MHz and RT in kΩ
Note 1: This table uses 1A for the peak switch current. Refer to the
Electrical Characteristics Table and Typical Performance Characteristics
plots for the peak switch current at an operating duty cycle.
Note 2: The final values for COUT and CIN may deviate from the previous
equations in order to obtain desired load transient performance.
LT8580
23
8580f
For more information www.linear.com/LT8580
Figure 16. SEPIC Converter: The Component Values and Voltages
Given Are Typical Values for a 1MHz, 9V to 16V Input to 12V
Output SEPIC Converter
applicaTions inForMaTion
COUT
4.7µF
VOUT
12V
240mA
L1
22µH D1
C1
F
RFBX
130k
VIN
9V TO 16V
VIN SW
8580 F16
LT8580
487k
RC
16.2k
RT
84.5k
SHDN
GND
FBX
VCSYNC
SSRT
CC
1nF
CF
22pF
CSS
0.22µF
CIN
4.7µF
L2
22µH
SEPIC CONVERTER COMPONENT SELECTION
(COUPLED OR UNCOUPLED INDUCTORS)
The LT8580 can also be configured as a SEPIC, as shown
in Figure 16. This topology allows for positive output volt-
ages that are lower, equal or higher than the input volt-
age. Output disconnect is inherently built into the SEPIC
topology, meaning no DC path exists between the input
and output due to capacitor C1.
Table 5 is a step-by-step set of equations to calculate com-
ponent values for the LT8580 when operating as a SEPIC
converter. Input parameters are input and output voltage,
and switching frequency (VIN, VOUT and fOSC, respectively).
Refer to the Applications Information section for further
information on the design equations presented in Table 5.
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Average Output Current
IRIPPLE = Inductor Ripple Current
Table 5. SEPIC Design Equations
PARAMETERS/EQUATIONS
Step 1:
Inputs
Pick VIN, VOUT and fOSC to calculate equations below
Step 2:
DC
DCMAX =VOUT +0.5V
VIN(MIN) +VOUT +0.5 V 0.4V
DCMIN =VOUT +0.5V
VIN(MAX) +VOUT +0.5 V 0.4V
Step 3:
L
LTYP =(VIN(MIN) 0.4V)DCMAX
fOSC 0.3A
(1)
LMIN =(VIN(MIN) 0.4V)(2 DCMAX 1)
1.25 (DCMAX 300nS fOSC)fOSC (1– DCMAX )
(2)
LMAX =(VIN(MIN) 0.4V)DCMAX
fOSC 0.08A
(3)
•Solve equations 1, 2 and 3 for a range of L values
•The minimum of the L value range is the higher of LTYP and LMIN
•The maximum of the L value range is LMAX
•L = L1 = L2 for coupled inductors
•L = L1|| L2 for uncoupled inductors
Step 4:
IRIPPLE
IRIPPLE(MIN) =
(V
IN(MIN)
0.4V)DC
MAX
fOSC L
IRIPPLE(MAX) =(VIN(MAX) 0.4V)DCMIN
fOSC L
Step 5:
IOUT
IOUT(MIN) =1A IRIPPLE(MIN)
2
1DCMAX
( )
IOUT(MAX) =1A IRIPPLE(MAX)
2
1DCMIN
( )
Step 6:
D1
VR > VIN + VOUT; IAVG > IOUT
Step 7:
C1
C1 ≥ 1µF; VRATING ≥ VIN
Step 8:
COUT
COUT IOUT(MIN) DCMAX
fOSC 0.005 VOUT
Step 9:
CIN
CIN CVIN +CPWR
1A DCMAX
40 fOSC 0.005 VIN(MIN)
+IRIPPLE(MAX)
8fOSC 0.005 VIN(MAX)
•Refer to the Capacitor Selection Section for definition of CVIN and CPWR
Step 10:
RFBX
RFBX =VOUT 1.204V
83.3µA
Step 11:
RT
RT=
85.5
fOSC
1; fOSC in MHz and RT in kΩ
Note 1: This table uses 1A for the peak switch current. Refer to the
Electrical Characteristics Table and Typical Performance Characteristics
plots for the peak switch current at an operating duty cycle.
Note 2: The final values for COUT, CIN and C1 may deviate from the
previous equations in order to obtain desired load transient performance.
LT8580
24
8580f
For more information www.linear.com/LT8580
applicaTions inForMaTion
Figure 17. Dual Inductor Inverting Converter: The Component
Values and Voltages Given Are Typical Values for a 750kHz
Wide Input (5V to 40V) to –15V Inverting Topology Using
Coupled Inductors
COUT
4.7µF
VOUT
–15V
90mA (VIN = 5V)
210mA (VIN = 12V)
420mA (VIN = 40V)
L1
22µH L2
22µH
C1
F
D1
RFBX
182k
VIN
5V TO 40V
VIN SW
8580 F17
LT8580
10k
RC
13.7k
RT
113k
SHDN
GND
FBX
VCSYNC
SSRT
CC
10nF
CF
47pF
CSS
0.22µF
CIN
4.7µF
DUAL INDUCTOR INVERTING CONVERTER COMPONENT
SELECTION (COUPLED OR UNCOUPLED INDUCTORS)
Due to its unique FBX pin, the LT8580 can work in a dual
inductor inverting configuration as in Figure 17. Chang-
ing the connections of L2 and the Schottky diode in the
SEPIC topology results in generating negative output
voltages. This solution results in very low output voltage
ripple due to inductor L2 being in series with the output.
Output disconnect is inherently built into this topology
due to the capacitor C1.
Table 6 is a step-by-step set of equations to calculate
component values for the LT8580 when operating as a
dual inductor inverting converter. Input parameters are
input and output voltage, and switching frequency (VIN,
VOUT and fOSC respectively). Refer to the Applications
Information section for further information on the design
equations presented in Table 6.
Variable Definitions:
VIN = Input Voltage
VOUT = Output Voltage
DC = Power Switch Duty Cycle
fOSC = Switching Frequency
IOUT = Maximum Average Output Current
IRIPPLE = Inductor Ripple Current
Table 6. Dual Inductor Inverting Design Equations
PARAMETERS/EQUATIONS
Step 1:
Inputs
Pick VIN, VOUT and fOSC to calculate equations below
Step 2:
DC
DCMAX =VOUT +0.5V
VIN(MIN) +VOUT +0.5 V 0.4V
DCMIN =VOUT +0.5V
VIN(MAX) +VOUT +0.5V 0.4 V
Step 3:
L
LTYP =(VIN(MIN) 0.4V)DCMAX
fOSC 0.3A
(1)
LMIN =(VIN(MIN) 0.4V)(2 DCMAX 1)
1.25 (DCMAX 300nS fOSC)fOSC (1– DCMAX )
(2)
LMAX =(VIN(MIN) 0.4V)DCMAX
fOSC 0.08A
(3)
•Solve equations 1, 2 and 3 for a range of L values
•The minimum of the L value range is the higher of LTYP and LMIN
•The maximum of the L value range is LMAX
•L = L1 = L2 for coupled inductors
•L = L1|| L2 for uncoupled inductors
Step 4:
IRIPPLE
IRIPPLE(MIN) =(VIN(MIN) 0.4V)DCMAX
fOSC L
IRIPPLE(MAX) =(VIN(MAX) 0.4V)DCMIN
fOSC L
Step 5:
IOUT
IOUT(MIN) =1A IRIPPLE(MIN)
2
1DCMAX
( )
IOUT(MAX) =1A IRIPPLE(MAX)
2
1DCMIN
( )
Step 6:
D1
VR > VIN + |VOUT|; IAVG > IOUT
Step 7:
C1
C1 ≥ 1µF; VRATING ≥ VIN(MAX) + |VOUT|
Step 8:
COUT
COUT IRIPPLE(MAX)
8fOSC (0.005 VOUT )
Step 9:
CIN
CIN CVIN +CPWR
1A DCMAX
40 fOSC 0.005 VIN(MIN)
+IRIPPLE(MAX)
8fOSC 0.005 VIN(MAX)
•Refer to the Capacitor Selection Section for definition of CVIN and CPWR
Step 10:
RFBX
RFBX =VOUT +3mV
83.3µA
Step 11:
RT
RT=
85.5
fOSC
1; fOSC in MHz and RT in kΩ
Note 1: This table uses 1A for the peak switch current. Refer to the
Electrical Characteristics Table and Typical Performance Characteristics
plots for the peak switch current at an operating duty cycle.
Note 2: The final values for COUT, CIN and C1 may deviate from the
previous equations in order to obtain desired load transient performance.
LT8580
25
8580f
For more information www.linear.com/LT8580
Typical applicaTions
1.5MHz, 5V to 12V Output Boost Converter
50mA to 150mA to 50mA Output Load Step
Efficiency and Power Loss
COUT
4.7µF
VOUT
12V
200mA
L1
15µH D1
130k
VIN
5V
VIN SW
8580 TA02a
LT8580
10k
6.04k
56.2k
SHDN
GND
FBX
VCSYNC
SSRT
3.3nF
47pF
0.22µF
L1: WÜRTH 15µH WE-LQS 74404054150
D1: DIODES INC. SBR1U40LP
CIN: 2.2µF, 35V, 0805, X7R
COUT: 4.7µF, 16V, 0805, X7R
CIN
2.2µF
LOAD CURRENT (mA)
0
20
EFFICIENCY (%)
POWER LOSS (mW)
40
50
60
100
100
8580 TA02b
30
50 150 200
70
80
90
0
180
300
480
240
60
120
380
420
EFFICIENCY
POWER LOSS
VOUT
500mV/DIV
AC-COUPLED
ISTEP
100mA/DIV
IL1
500mA/DIV
100µs/DIV 8580 TA02c
LT8580
26
8580f
For more information www.linear.com/LT8580
750kHz, –15V Output Inverting Converter Accepts 5V to 40V Input
Typical applicaTions
Efficiency and Power Loss (VIN = 12V)
60mA to 160mA to 60mA Output Load Step (VIN = 12V)
COUT
4.7µF
VOUT
–15V
90mA (VIN = 5V)
210mA (VIN = 12V)
420mA (VIN = 40V)
L1
22µH L2
22µH
C1
F
D1
182k
VIN
5V TO 40V
VIN SW
8580 TA03a
LT8580
10k
13.7k
113k
SHDN
GND
FBX
VCSYNC
SSRT
10nF
47pF
0.22µF
CIN
4.7µF
L1, L2: COILCRAFT 22µH MSD7342-223
D1: CENTRAL SEMI CMMSH1-60
CIN: 4.7µF, 50V, 1206, X5R
COUT: 4.7µF, 25V, 1206, X7R
C1: 1µF, 100V, 0805, X7S
LOAD CURRENT (mA)
0
10
EFFICIENCY (%)
POWER LOSS (mW)
30
40
50
100
90
8580 TA03b
20
50 150 200
60
70
80
0
240
400
640
320
80
160
480
560
EFFICIENCY
POWER LOSS
VOUT
200mV/DIV
AC-COUPLED
ISTEP
100mA/DIV
IL1 + IL2
200mA/DIV
200µs/DIV 8580 TA03c
LT8580
27
8580f
For more information www.linear.com/LT8580
Typical applicaTions
1.2MHz Inverting Converter Generates –48V Output From 12V Input
Switching Waveforms
Efficiency and Power Loss
Start-Up Waveforms
COUT
2.2µF
VOUT
–48V
70mA
L1
150µH L2
330µH
C1
F
D1
576k
VIN
12V
VIN SW
8580 TA04a
LT8580
619k
20.5k
69.8k
SHDN
GND
FBX
VCSYNC
SSRT
4.7nF
47pF
0.33µF
CIN
1µF
C2
2.2µF
L1: COOPER 150µH DR74-151
L2: COOPER 330µH DR74-331
D1: DIODES, INC. DFLS1100
CIN: 1µF, 50V, 0805, X7R
COUT: 2.2µF, 100V, 1206, X7R
C1: 1µF, 100V, 0805, X7S
C2: 2.2µF, 100V, 1206, X7S
49.9Ω
LOAD CURRENT (mA)
0
20
EFFICIENCY (%)
POWER LOSS (mW)
30
40
50
50
90
8580 TA04b
40 602010 30 70
60
70
80
200
560
800
1040
680
320
440
920
EFFICIENCY
POWER LOSS
VOUT
20mV/DIV
AC-COUPLED
VSW
20V/DIV
IL1 + IL2
200mA/DIV
200µs/DIV
8580 TA04c
VOUT
10V/DIV
VSW
20V/DIV
IL1 + IL2
200mA/DIV
200µs/DIV
8580 TA04d
LT8580
28
8580f
For more information www.linear.com/LT8580
Typical applicaTions
Start-Up Waveforms
VFD (Vacuum Fluorescent Display) Power Supply Switches at 1MHz
Danger High Voltage! Operation by High Voltage Trained Personnel Only
Efficiency and Power Loss
(VIN = 12V with Load on VOUT3)
C1
F
VOUT1
60V
60mA*
VOUT3
180V
20mA*
VOUT2
120V
30mA*
L1
68µH C2
F D1
698k
VIN
9V TO 16V
VIN SW
8580 TA05a
LT8580
487k
22.1k
84.5k
SHDN
GND
FBX
VCSYNC
SSRT
4.7nF
330pF
0.47µF
CIN
1µF
C4
F
C3
F
C5
F
D3
D2
L1: WÜRTH 68µH WE-LQS 74404084680
D1-D5: DIODES, INC. DFLS1100
CIN: 1µF, 100V, 1206, X7R
C1-C5: 1µF, 100V, 1206, X7S
*MAX TOTAL OUTPUT POWER 3.5W
22Ω
D4
22Ω
D5
OUTPUT POWER (W)
0
20
EFFICIENCY (%)
POWER LOSS (mW)
30
40
50
2.5
90
8580 TA05b
2 310.5 1.5 3.5
60
70
80
400
640
800
960
720
480
560
880
EFFICIENCY
POWER LOSS
VOUT3
50V/DIV
VOUT2
50V/DIV
VOUT1
50V/DIV
IL1
200mA/DIV
2ms/DIV 8580 TA05c
LT8580
29
8580f
For more information www.linear.com/LT8580
550kHz SEPIC Converter Generates 24V from 15V to 30V Input
Transient Response with 100mA to 225mA
to 100mA Output Load Step (VIN = 24V)
Typical applicaTions
Efficiency and Power Loss
(VIN = 24V)
LOAD CURRENT (mA)
0
10
EFFICIENCY (%)
POWER LOSS (mW)
30
20
40
50
200
90
8580 TA06b
150 25050 100 300
60
70
80
200
800
1100
1400
950
500
350
650
1250
EFFICIENCY
POWER LOSS
VOUT
500mV/DIV
AC-COUPLED
ISTEP
100mA/DIV
IL1 + IL2
500mA/DIV
100µs/DIV
8580 TA06c
COUT
4.7µF
VOUT
24V
195mA (VIN = 15V)
300mA (VIN = 24V)
L1
47µH
L2
47µH
C1
F D1
274k
VIN
15V TO 30V
VIN SW
8580 TA06a
LT8580
1M
12.7k
154k
SHDN
GND
FBX
VCSYNC
SSRT
3.3nF
22pF
0.1µF
CIN
2.2µF
L1, L2: COILCRAFT 47µH MSD7342-473
D1: DIODES INC. DFLS1100
CIN: 2.2µF, 35V, 0805, X7R
COUT: 4.7µF, 35V, 1206, X7R
C1: 1µF, 100V, 0805, X7S
LT8580
30
8580f
For more information www.linear.com/LT8580
3.00 ±0.10
(4 SIDES)
NOTE:
1. DRAWING TO BE MADE A JEDEC PACKAGE OUTLINE M0-229 VARIATION OF (WEED-1)
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 TOP AND BOTTOM OF PACKAGE
0.40 ±0.10
BOTTOM VIEW—EXPOSED PAD
1.65 ±0.10
(2 SIDES)
0.75 ±0.05
R = 0.125
TYP
2.38 ±0.10
14
85
PIN 1
TOP MARK
(NOTE 6)
0.200 REF
0.00 – 0.05
(DD8) DFN 0509 REV C
0.25 ±0.05
2.38 ±0.05
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
APPLY SOLDER MASK TO AREAS THAT ARE NOT SOLDERED
1.65 ±0.05
(2 SIDES)2.10 ±0.05
0.50
BSC
0.70 ±0.05
3.5 ±0.05
PACKAGE
OUTLINE
0.25 ±0.05 0.50 BSC
DD Package
8-Lead Plastic DFN (3mm × 3mm)
(Reference LTC DWG # 05-08-1698 Rev C)
package DescripTion
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
LT8580
31
8580f
For more information www.linear.com/LT8580
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 representa-
tion that the interconnection of its circuits as described herein will not infringe on existing patent rights.
package DescripTion
Please refer to http://www.linear.com/designtools/packaging/ for the most recent package drawings.
MSOP (MS8E) 0213 REV K
0.53 ±0.152
(.021 ±.006)
SEATING
PLANE
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
6. EXPOSED PAD DIMENSION DOES INCLUDE MOLD FLASH. MOLD FLASH ON E-PAD
SHALL NOT EXCEED 0.254mm (.010") PER SIDE.
0.18
(.007)
0.254
(.010)
1.10
(.043)
MAX
0.22 – 0.38
(.009 – .015)
TYP
0.86
(.034)
REF
0.65
(.0256)
BSC
0° – 6° TYP
DETAIL “A”
DETAIL “A”
GAUGE PLANE
1 2 34
4.90 ±0.152
(.193 ±.006)
8
8
1
BOTTOM VIEW OF
EXPOSED PAD OPTION
765
3.00 ±0.102
(.118 ±.004)
(NOTE 3)
3.00 ±0.102
(.118 ±.004)
(NOTE 4)
0.52
(.0205)
REF
1.68
(.066)
1.88
(.074)
5.10
(.201)
MIN
3.20 – 3.45
(.126 – .136)
1.68 ±0.102
(.066 ±.004)
1.88 ±0.102
(.074 ±.004) 0.889 ±0.127
(.035 ±.005)
RECOMMENDED SOLDER PAD LAYOUT
0.65
(.0256)
BSC
0.42 ±0.038
(.0165 ±.0015)
TYP
0.1016 ±0.0508
(.004 ±.002)
DETAIL “B”
DETAIL “B”
CORNER TAIL IS PART OF
THE LEADFRAME FEATURE.
FOR REFERENCE ONLY
NO MEASUREMENT PURPOSE
0.05 REF
0.29
REF
MS8E Package
8-Lead Plastic MSOP, Exposed Die Pad
(Reference LTC DWG # 05-08-1662 Rev K)
LT8580
32
8580f
For more information www.linear.com/LT8580
LINEAR TECHNOLOGY CORPORATION 2014
LT 0714 • PRINTED IN USA
Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 FAX: (408) 434-0507 www.linear.com/LT8580
relaTeD parTs
Typical applicaTion
PART NUMBER DESCRIPTION COMMENTS
LT1310 2A (ISW), 40V, 1.2MHz High Efficiency Step-Up DC/DC Converter VIN: 2.3V to 16V, VOUT(MAX) = 40V, IQ = 3mA, ISD < 1µA,
ThinSOT™ Package
LT1613 550mA (ISW), 1.4MHz High Efficiency Step-Up DC/DC Converter VIN: 0.9V to 10V, VOUT(MAX) = 34V, IQ = 3mA, ISD < 1µA,
ThinSOT Package
LT1618 1.5A (ISW), 1.25MHz High Efficiency Step-Up DC/DC Converter VIN: 1.6V to 18V, VOUT(MAX) = 35V, IQ = 1.8mA, ISD < 1µA,
MS10 Package
LT1930/LT1930A 1A (ISW), 1.2MHz/2.2MHz High Efficiency Step-Up DC/DC
Converter VIN: 2.6V to 16V, VOUT(MAX) = 34V, IQ = 4.2mA/5.5mA, ISD < 1µA,
ThinSOT Package
LT1935 2A (ISW), 40V, 1.2MHz High Efficiency Step-Up DC/DC Converter VIN: 2.3V to 16V, VOUT(MAX) = 40V, IQ = 3mA, ISD < 1µA,
ThinSOT Package
LT1944/LT1944-1 Dual Output 350mA (ISW), Constant Off-Time, High Efficiency
Step-Up DC/DC Converter VIN: 1.2V to 15V, VOUT(MAX) = 34V, IQ = 20µA, ISD < 1µA,
MS10 Package
LT1946/LT1946A 1.5A (ISW), 1.2MHz/2.7MHz High Efficiency Step-Up DC/DC
Converter VIN: 2.6V to 16V, VOUT(MAX) = 34V, IQ = 3.2mA, ISD < 1µA,
MS8E Package
LT3467 1.1A (ISW), 1.3MHz High Efficiency Step-Up DC/DC Converter VIN: 2.6V to 16V, VOUT(MAX) = 40V, IQ = 1.2mA, ISD < 1µA,
ThinSOT, 2mm × 3mm DFN Packages
LT3477 42V, 3A, 3.5MHz Boost, Buck-Boost, Buck LED Driver VIN: 2.5V to 25V, VOUT(MAX) = 40V, Analog/PWM, ISD < 1µA,
QFN, TSSOP-20E Packages
LT3479 3A Full-Featured DC/DC Converter with Soft-Start and Inrush
Current Protection VIN: 2.5V to 24V, VOUT(MAX) = 40V, Analog/PWM, ISD < 1µA,
DFN, TSSOP Packages
LT3580 2A (ISW), 42V, 2.5MHz, High Efficiency Step-Up DC/DC
Converter VIN: 2.5V to 32V, VOUT(MAX) = 42V, IQ = 1mA, ISD = <1µA,
3mm × 3mm DFN-14, MSOP-16E
LT3581 3.3A (ISW), 42V, 2.5MHz, High Efficiency Step-Up DC/DC
Converter VIN: 2.5V to 22V, VOUT(MAX) = 42V, IQ = 1.9mA, ISD = <1µA,
4mm × 3mm DFN-14, MSOP-16E
LT3579 6A (ISW), 42V, 2.5MHz, High Efficiency, Step-Up DC/DC
Converter VIN: 2.5V to 16V, VOUT(MAX) = 42V, IQ = 1.9mA, ISD = <1µA,
4mm × 5mm DFN-20, TSSOP-20
LT8582 Dual Channel, 3A (ISW), 42V, 2.5MHz, High Efficiency Step-Up
DC/DC Converter VIN: 2.5V to 22V, VOUT(MAX) = 42V, IQ = 2.1mA, ISD = <1µA,
4mm × 7mm DFN-24
Efficiency and Power Loss
(VIN = 12V)
12V Battery Stabilizer Survives 40V Transients
COUT
4.7µF
VOUT
12V
240mA
L1
22µH
L2
22µH
C1
F D1
130k
VIN
9V TO 16V
UP TO 40V
TRANSIENT
VIN SW
8580 TA07a
LT8580
487k
16.2k
84.5k
SHDN
GND
FBX
VCSYNC
SSRT
1nF
22pF
0.22µF
CIN
4.7µF
L1, L2: WÜRTH 22µH WE-DD 744877220
D1: DIODES INC. DFLS1100
CIN: 4.7µF, 50V, 1206, X7R
COUT: 4.7µF, 25V, 1206, X7R
C1: 1µF, 100V, 0805, X7S
LOAD CURRENT (mA)
0
10
EFFICIENCY (%)
POWER LOSS (mW)
30
20
40
50
160
90
8580 TA07b
120 20040 80 240
60
70
80
0
400
600
800
500
200
100
300
700
EFFICIENCY
POWER LOSS