LINER 1956I5

LT1956/LT1956-5
High Voltage, 1.5A,
500kHz Step-Down
Switching Regulators
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FEATURES
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DESCRIPTIO
The LT ®1956/LT1956-5 are 500kHz monolithic buck
switching regulators with an input voltage capability up to
60V. A high efficiency 1.5A, 0.2Ω switch is included on the
die along with all the necessary oscillator, control and logic
circuitry. A current mode architecture provides fast transient response and good loop stability.
Wide Input Range: 5.5V to 60V
1.5A Peak Switch Current
Small 16-Pin SSOP or Thermally Enhanced
TSSOP Package
Saturating Switch Design: 0.2Ω
Peak Switch Current Maintained Over
Full Duty Cycle Range
Constant 500kHz Switching Frequency
Effective Supply Current: 2.5mA
Shutdown Current: 25µA
1.2V Feedback Reference (LT1956)
5V Fixed Output (LT1956-5)
Easily Synchronizable
Cycle-by-Cycle Current Limiting
Special design techniques and a new high voltage process
achieve high efficiency over a wide input range. Efficiency
is maintained over a wide output current range by using the
output to bias the circuitry and by utilizing a supply boost
capacitor to saturate the power switch. Patented circuitry
maintains peak switch current over the full duty cycle
range*. A shutdown pin reduces supply current to 25µA and
the device can be externally synchronized from 580kHz to
700kHz with a logic level input.
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APPLICATIO S
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The LT1956/LT1956-5 are available in fused-lead 16-pin
SSOP and thermally enhanced TSSOP packages.
High Voltage, Industrial and Automotive
Portable Computers
Battery-Powered Systems
Battery Chargers
Distributed Power Systems
, LTC and LT are registered trademarks of Linear Technology Corporation.
*U.S. PATENT NO. 6,498,466
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TYPICAL APPLICATIO
5V Buck Converter
Efficiency vs Load Current
MMSD914TI
100
VIN = 12V
L = 18µH
6
BOOST
4
2.2µF†
100V
CERAMIC
SW
VIN
2
10MQ060N
LT1956-5
15
14
SHDN
SYNC
GND
10µH
BIAS
FB
10
VOUT
5V
1A
22µF
6.3V
CERAMIC
90
EFFICIENCY (%)
VIN
12V
(TRANSIENTS
TO 60V)
0.1µF
VOUT = 5V
VOUT = 3.3V
80
70
12
60
VC
1, 8, 9, 16 11
50
220pF
4.7k
0
0.25
0.75
1.00
0.50
LOAD CURRENT (A)
1.25
1956 TA02
4700pF
†
UNITED CHEMI-CON THCS50EZA225ZT
1956 TA01
1956f
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LT1956/LT1956-5
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ABSOLUTE
RATI GS
(Note 1)
Input Voltage (VIN) ................................................. 60V
BOOST Pin Above SW ............................................ 35V
BOOST Pin Voltage ................................................. 68V
SYNC, SENSE Voltage (LT1956-5) ........................... 7V
SHDN Voltage ........................................................... 6V
BIAS Pin Voltage .................................................... 30V
FB Pin Voltage/Current (LT1956) ................... 3.5V/2mA
Operating Junction Temperature Range
LT1956EFE/LT1956EFE-5/LT1956EGN/LT1956EGN-5
(Notes 8, 10) ..................................... – 40°C to 125°C
LT1956IFE/LT1956IFE-5/LT1956IGN/LT1956IGN-5
(Notes 8, 10) ..................................... – 40°C to 125°C
Storage Temperature Range ................ – 65°C to 150°C
Lead Temperature (Soldering, 10 sec)................. 300°C
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PACKAGE/ORDER I FOR ATIO
TOP VIEW
GND
1
16 GND
SW
2
15 SHDN
NC
3
14 SYNC
VIN
4
13 NC
NC
5
12 FB/SENSE
BOOST
6
11 VC
NC
7
10 BIAS
GND
8
9
GND
FE PACKAGE
16-LEAD PLASTIC TSSOP
TJMAX = 125°C, θJA = 45°C/ W, θJC (PAD) = 10°C/ W
EXPOSED BACKSIDE MUST BE SOLDERED
TO GROUND PLANE
ORDER PART
NUMBER
LT1956EFE
LT1956IFE
LT1956EFE-5
LT1956IFE-5
FE PART MARKING
1956EFE
1956IFE
1956EFE-5
1956IFE-5
ORDER PART
NUMBER
TOP VIEW
GND
1
16 GND
SW
2
15 SHDN
NC
3
14 SYNC
VIN
4
13 NC
NC
5
12 FB/SENSE
BOOST
6
11 VC
NC
7
10 BIAS
GND
8
9
LT1956EGN
LT1956IGN
LT1956EGN-5
LT1956IGN-5
GN PART MARKING
GND
1956
1956I
19565
1956I5
GN PACKAGE
16-LEAD PLASTIC SSOP
TJMAX = 125°C, θJA = 85°C/ W, θJC (PIN 8) = 25°C/ W
FOUR CORNER PINS SOLDERED
TO GROUND PLANE
Consult LTC Marketing for parts specified with wider operating temperature ranges.
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are at TJ = 25°C.
VIN = 15V, VC = 1.5V, SHDN = 1V, Boost o/c, SW o/c, unless otherwise noted.
PARAMETER
CONDITIONS
Reference Voltage (LT1956)
5.5V ≤ VIN ≤ 60V
VOL + 0.2 ≤ VC ≤ VOH – 0.2
5.5V ≤ VIN ≤ 60V
VOL + 0.2 ≤ VC ≤ VOH – 0.2
SENSE Voltage (LT1956-5)
MIN
TYP
MAX
UNITS
1.204
1.195
1.219
●
1.234
1.243
V
V
4.94
4.90
5
●
5.06
5.10
V
V
9.5
13.8
19
kΩ
0.5
1.5
µA
SENSE Pin Resistance (LT1956-5)
FB Input Bias Current (LT1956)
●
Error Amp Voltage Gain
(Notes 2, 9)
200
400
Error Amp gm
dl (VC) = ±10µA (Note 9)
1500
1000
2000
●
VC to Switch gm
V/V
3000
3200
1.7
µMho
µMho
A/V
EA Source Current
FB = 1V or VSENSE = 4.1V
●
125
225
400
µA
EA Sink Current
FB = 1.4V or VSENSE = 5.7V
●
100
225
450
µA
VC Switching Threshold
Duty Cycle = 0
0.9
VC High Clamp
SHDN = 1V
2.1
V
V
1956f
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LT1956/LT1956-5
ELECTRICAL CHARACTERISTICS
The ● denotes specifications which apply over the full operating temperature range, otherwise specifications are at TJ = 25°C.
VIN = 15V, VC = 1.5V, SHDN = 1V, Boost o/c, SW o/c, unless otherwise noted.
PARAMETER
CONDITIONS
MIN
TYP
MAX
Switch Current Limit
VC Open, Boost = VIN + 5V, FB = 1V or VSENSE = 4.1V ●
1.5
2
3
A
Switch On Resistance
ISW = 1.5A, Boost = VIN + 5V (Note 7)
0.2
0.3
0.4
Ω
Ω
●
Maximum Switch Duty Cycle
Switch Frequency
FB = 1V or VSENSE = 4.1V
UNITS
●
82
75
90
90
460
430
500
●
540
570
kHz
kHz
0.05
0.15
%/V
VC Set to Give DC = 50%
%
%
fSW Line Regulation
5.5V ≤ VIN ≤ 60V
fSW Shifting Threshold
Df = 10kHz
Minimum Input Voltage
(Note 3)
●
Minimum Boost Voltage
(Note 4) ISW ≤ 1.5A
●
2
3
V
Boost Current (Note 5)
Boost = VIN + 5V, ISW = 0.5A
Boost = VIN + 5V, ISW = 1.5A
●
●
12
42
25
70
mA
mA
Input Supply Current (IVIN)
(Note 6) VBIAS = 5V
1.4
2.2
mA
Output Supply Current (IBIAS)
(Note 6) VBIAS = 5V
2.9
4.2
mA
Shutdown Supply Current
SHDN = 0V, VIN ≤ 60V, SW = 0V, VC Open
25
75
200
µA
µA
●
0.8
4.6
●
V
5.5
V
Lockout Threshold
VC Open
●
2.30
2.42
2.53
V
Shutdown Thresholds
VC Open, Shutting Down
VC Open, Starting Up
●
●
0.15
0.25
0.37
0.45
0.6
0.6
V
V
1.5
2.2
V
700
kHz
Minimum SYNC Amplitude
SYNC Frequency Range
SYNC Input Resistance
Note 1: Absolute Maximum Ratings are those values beyond which the life
of a device may be impaired.
Note 2: Gain is measured with a VC swing equal to 200mV above the low
clamp level to 200mV below the upper clamp level.
Note 3: Minimum input voltage is not measured directly, but is guaranteed
by other tests. It is defined as the voltage where internal bias lines are still
regulated so that the reference voltage and oscillator remain constant.
Actual minimum input voltage to maintain a regulated output will depend
upon output voltage and load current. See Applications Information.
Note 4: This is the minimum voltage across the boost capacitor needed to
guarantee full saturation of the internal power switch.
Note 5: Boost current is the current flowing into the BOOST pin with the
pin held 5V above input voltage. It flows only during switch on time.
Note 6: Input supply current is the quiescent current drawn by the input
pin when the BIAS pin is held at 5V with switching disabled. Bias supply
current is the current drawn by the BIAS pin when the BIAS pin is held at
5V. Total input referred supply current is calculated by summing input
supply current (IVIN) with a fraction of supply current (IBIAS):
ITOTAL = IVIN + (IBIAS)(VOUT/VIN)
with VIN = 15V, VOUT = 5V, IVIN = 1.4mA, IBIAS = 2.9mA, ITOTAL = 2.4mA.
●
580
20
kΩ
Note 7: Switch on resistance is calculated by dividing VIN to SW voltage by
the forced current (1.5A). See Typical Performance Characteristics for the
graph of switch voltage at other currents.
Note 8: The LT1956EFE/LT1956EFE-5/LT1956EGN/LT1956EGN-5 are
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 LT1956IFE/LT1956IFE-5/
LT1956IGN/LT1956IGN-5 are guaranteed over the full – 40°C to 125°C
operating junction temperature range.
Note 9: Transconductance and voltage gain refer to the internal amplifier
exclusive of the voltage divider. To calculate gain and transconductance,
refer to the SENSE pin on fixed voltage parts. Divide values shown by the
ratio VOUT/1.219.
Note 10: This IC includes overtemperature protection that is intended to
protect the device during momentary overload conditions. Junction
temperature will exceed 125°C when overtemperature protection is active.
Continuous operation above the specified maximum operating junction
temperature may impair device reliability.
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LT1956/LT1956-5
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TYPICAL PERFOR A CE CHARACTERISTICS
FB Pin Voltage and Current
Switch Peak Current Limit
SHDN Pin Bias Current
1.234
2.0
250
TYPICAL
2.0
GUARANTEED MINIMUM
1.5
1.5
1.224
VOLTAGE
1.219
1.0
CURRENT
1.214
150
100
12
0
20
40
60
DUTY CYCLE (%)
100
80
6
1.204
50
100
25
75
–50 –25
0
JUNCTION TEMPERATURE (°C)
1956 G01
0
50
100
–50 –25
25
75
0
JUNCTION TEMPERATURE (°C)
Shutdown Supply Current
300
40
LOCKOUT
VSHDN = 0V
1.2
0.8
START-UP
0.4
INPUT SUPPLY CURRENT (µA)
INPUT SUPPLY CURRENT (µA)
35
1.6
125
1956 G03
Shutdown Supply Current
2.4
SHDN PIN VOLTAGE (V)
0
125
1956 G02
Lockout and Shutdown
Thresholds
2.0
AT 2.38V STANDBY THRESHOLD
(CURRENT FLOWS OUT OF PIN)
0.5
1.209
1.0
CURRENT REQUIRED TO FORCE SHUTDOWN
(FLOWS OUT OF PIN). AFTER SHUTDOWN,
CURRENT DROPS TO A FEW µA
200
CURRENT (µA)
FEEDBACK VOLTAGE (V)
1.229
CURRENT (µA)
SWITCH PEAK CURRENT (A)
2.5
30
25
20
15
10
250
VIN = 60V
200
VIN = 15V
150
100
5
50
SHUTDOWN
0
0
–25
0
25
50
75
100
10
0
125
20
30
40
INPUT VOLTAGE (V)
JUNCTION TEMPERATURE (°C)
50
0
60
Error Amplifier Transconductance
1956 G06
Error Amplifier Transconductance
2500
3000
2000
2500
Frequency Foldback
200
625
GAIN (µMho)
1000
500
150
GAIN
2000
100
VC
(
)
ROUT
200k
COUT
12pF
1500
VFB 2 • 10–3
1000
ERROR AMPLIFIER EQUIVALENT CIRCUIT
50
0
PHASE (DEG)
TRANSCONDUCTANCE (µmho)
PHASE
1500
SWITCHING
FREQUENCY
500
375
250
125
FB PIN
CURRENT
RLOAD = 50Ω
0
–50
–25
0
25
50
75
100
125
JUNCTION TEMPERATURE
1956 G07
500
100
1k
10k
100k
FREQUENCY (Hz)
1M
–50
10M
1956 G08
0.5
0.1
0.2
0.3
0.4
SHUTDOWN VOLTAGE (V)
1956 G05
1956 G04
SWITICHING FREQUENCY (kHz)
OR FB CURRENT (µA)
0
–50
0
0
0.2
0.4
0.6
VFB (V)
0.8
1.0
1.2
1956 G09
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LT1956/LT1956-5
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TYPICAL PERFOR A CE CHARACTERISTICS
Minimum Input Voltage with 5V
Output
Switching Frequency
7.5
575
VOUT = 5V
L = 18µH
40
525
500
475
BOOST PIN CURRENT (mA)
7.0
INPUT VOLTAGE (V)
FREQUENCY (kHz)
550
BOOST Pin Current
45
MINIMUM INPUT
VOLTAGE TO START
6.5
6.0
MINIMUM INPUT
VOLTAGE TO RUN
5.5
450
35
30
25
20
15
10
5
–25
0
25
50
75
100
5.0
125
0
JUNCTION TEMPERATURE (°C)
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9
LOAD CURRENT (A)
1956 G10
2.1
600
400
SWITCH VOLTAGE (mV)
1.9
1.3
1.1
TJ = 125°C
350
300
TJ = 25°C
250
200
150
TJ = –40°C
100
0.9
1.5
Switch Minimum ON Time
vs Temperature
450
1.5
0.5
1
SWITCH CURRENT (A)
1956 G12
Switch Voltage Drop
1.7
0
1956 G11
VC Pin Shutdown Threshold
THRESHOLD VOLTAGE (V)
0
1
SWITCH MINIMUM ON TIME (ns)
425
–50
500
400
300
200
100
50
0.7
50
100
–50 –25
25
75
0
JUNCTION TEMPERATURE (°C)
125
1956 G13
0
0
0.5
1
SWITCH CURRENT (A)
1.5
0
–50
–25
0
25
50
75
100
125
JUNCTION TEMPERATURE (°C)
1766 G14
1956 G15
1956f
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LT1956/LT1956-5
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PI FU CTIO S
GND (Pins 1, 8, 9, 16): The GND pin connections act as
the reference for the regulated output, so load regulation
will suffer if the “ground” end of the load is not at the same
voltage as the GND pins of the IC. This condition will occur
when load current or other currents flow through metal
paths between the GND pins and the load ground. Keep the
paths between the GND pins and the load ground short
and use a ground plane when possible. For the FE package,
the exposed pad should be soldered to the copper GND
plane underneath the device. (See Applications Information—Layout Considerations.)
SW (Pin 2): The switch pin is the emitter of the on-chip
power NPN switch. This pin is driven up to the input pin
voltage during switch on time. Inductor current drives the
switch pin negative during switch off time. Negative voltage is clamped with the external catch diode. Maximum
negative switch voltage allowed is – 0.8V.
NC (Pins 3, 5, 7, 13): No Connection.
VIN (Pin 4): This is the collector of the on-chip power NPN
switch. VIN powers the internal control circuitry when a
voltage on the BIAS pin is not present. High dI/dt edges
occur on this pin during switch turn on and off. Keep the
path short from the VIN pin through the input bypass
capacitor, through the catch diode back to SW. All trace
inductance on this path will create a voltage spike at switch
off, adding to the VCE voltage across the internal NPN.
BOOST (Pin 6): The BOOST pin is used to provide a drive
voltage, higher than the input voltage, to the internal
bipolar NPN power switch. Without this added voltage, the
typical switch voltage loss would be about 1.5V. The
additional BOOST voltage allows the switch to saturate
and voltage loss approximates that of a 0.2Ω FET structure, but with much smaller die area.
BIAS (Pin 10): The BIAS pin is used to improve efficiency
when operating at higher input voltages and light load
current. Connecting this pin to the regulated output voltage forces most of the internal circuitry to draw its operating current from the output voltage rather than the input
supply. This architecture increases efficiency especially
when the input voltage is much higher than the output.
Minimum output voltage setting for this mode of operation
is 3V.
VC (Pin 11) The VC pin is the output of the error amplifier
and the input of the peak switch current comparator. It is
normally used for frequency compensation, but can also
serve as a current clamp or control loop override. VC sits
at about 1V for light loads and 2V at maximum load. It can
be driven to ground to shut off the regulator, but if driven
high, current must be limited to 4mA.
FB/SENSE (Pin 12): The feedback pin is used to set the
output voltage using an external voltage divider that generates 1.22V at the pin for the desired output voltage. The
5V fixed output voltage parts have the divider included on
the chip and the FB pin is used as a SENSE pin, connected
directly to the 5V output. Three additional functions are
performed by the FB pin. When the pin voltage drops
below 0.6V, switch current limit is reduced and the external SYNC function is disabled. Below 0.8V, switching
frequency is also reduced. See Feedback Pin Functions in
Applications Information for details.
SYNC (Pin 14): The SYNC pin is used to synchronize the
internal oscillator to an external signal. It is directly logic
compatible and can be driven with any signal between
10% and 90% duty cycle. The synchronizing range is
equal to initial operating frequency up to 700kHz. See
Synchronizing in Applications Information for details. If
unused, this pin should be tied to ground.
SHDN (Pin 15): The SHDN pin is used to turn off the
regulator and to reduce input current to a few microamperes. This pin has two thresholds: one at 2.38V to disable
switching and a second at 0.4V to force complete micropower shutdown. The 2.38V threshold functions as an
accurate undervoltage lockout (UVLO); sometimes used
to prevent the regulator from delivering power until the
input voltage has reached a predetermined level.
If the SHDN pin functions are not required, the pin can
either be left open (to allow an internal bias current to lift
the pin to a default high state) or be forced high to a level
not to exceed 6V.
1956f
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LT1956/LT1956-5
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BLOCK DIAGRA
The LT1956 is a constant frequency, current mode buck
converter. This means that there is an internal clock and
two feedback loops that control the duty cycle of the power
switch. In addition to the normal error amplifier, there is a
current sense amplifier that monitors switch current on a
cycle-by-cycle basis. A switch cycle starts with an oscillator pulse which sets the RS flip-flop to turn the switch on.
When switch current reaches a level set by the inverting
input of the comparator, the flip-flop is reset and the
switch turns off. Output voltage control is obtained by
using the output of the error amplifier to set the switch
current trip point. This technique means that the error
amplifier commands current to be delivered to the output
rather than voltage. A voltage fed system will have low
phase shift up to the resonant frequency of the inductor
and output capacitor, then an abrupt 180° shift will occur.
The current fed system will have 90° phase shift at a much
lower frequency, but will not have the additional 90° shift
until well beyond the LC resonant frequency. This makes
VIN
it much easier to frequency compensate the feedback loop
and also gives much quicker transient response.
Most of the circuitry of the LT1956 operates from an
internal 2.9V bias line. The bias regulator normally draws
power from the regulator input pin, but if the BIAS pin is
connected to an external voltage higher than 3V, bias
power will be drawn from the external source (typically the
regulated output voltage). This will improve efficiency if
the BIAS pin voltage is lower than regulator input voltage.
High switch efficiency is attained by using the BOOST pin
to provide a voltage to the switch driver which is higher
than the input voltage, allowing switch to be saturated.
This boosted voltage is generated with an external capacitor and diode. Two comparators are connected to the
shutdown pin. One has a 2.38V threshold for undervoltage
lockout and the second has a 0.4V threshold for complete
shutdown.
4
RSENSE
RLIMIT
BIAS 10
2.9V BIAS
REGULATOR
–
+
INTERNAL
VCC
CURRENT
COMPARATOR
Σ
SLOPE COMP
SYNC 14
BOOST
ANTISLOPE COMP
6
SHUTDOWN
COMPARATOR
500kHz
OSCILLATOR
S
RS
FLIP-FLOP
Q1
POWER
SWITCH
DRIVER
CIRCUITRY
–
R
+
0.4V
5.5µA
2
SW
+
FREQUENCY
FOLDBACK
–
LOCKOUT
COMPARATOR
×1
2.38V
Q2
FOLDBACK
CURRENT
LIMIT
CLAMP
Q3
11
VC
ERROR
AMPLIFIER
gm = 2000µMho
12 FB
+
VC(MAX)
CLAMP
–
SHDN 15
1.22V
GND
1, 8, 9, 16
1956 F01
Figure 1. LT1956 Block Diagram
1956f
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LT1956/LT1956-5
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APPLICATIO S I FOR ATIO
FEEDBACK PIN FUNCTIONS
The feedback (FB) pin on the LT1956 is used to set output
voltage and provide several overload protection features.
The first part of this section deals with selecting resistors
to set output voltage and the remaining part talks about
foldback frequency and current limiting created by the FB
pin. Please read both parts before committing to a final
design. The 5V fixed output voltage part (LT1956-5) has
internal divider resistors and the FB pin is renamed SENSE,
connected directly to the output.
The suggested value for the output divider resistor (see
Figure 2) from FB to ground (R2) is 5k or less, and a
formula for R1 is shown below. The output voltage error
caused by ignoring the input bias current on the FB pin is
less than 0.25% with R2 = 5k. A table of standard 1%
values is shown in Table 1 for common output voltages.
Please read the following section if divider resistors are
increased above the suggested values.
R1 =
R2( VOUT − 1.22)
1.22
Table 1
OUTPUT
VOLTAGE
(V)
R2
(kΩ)
R1
(NEAREST 1%)
(kΩ)
% ERROR AT OUTPUT
DUE TO DISCRETE 1%
RESISTOR STEPS
3
4.99
7.32
+ 0.32
3.3
4.99
8.45
– 0.43
5
4.99
15.4
– 0.30
6
4.75
18.7
+ 0.38
8
4.47
24.9
+ 0.20
10
4.32
30.9
– 0.54
12
4.12
36.5
+ 0.24
15
4.12
46.4
– 0.27
More Than Just Voltage Feedback
The feedback pin is used for more than just output voltage
sensing. It also reduces switching frequency and current
limit when output voltage is very low (see the Frequency
Foldback graph in Typical Performance Characteristics).
This is done to control power dissipation in both the IC
and in the external diode and inductor during short-circuit
conditions. A shorted output requires the switching regulator to operate at very low duty cycles, and the average
current through the diode and inductor is equal to the
short-circuit current limit of the switch (typically 2A for
the LT1956, folding back to less than 1A). Minimum
switch on time limitations would prevent the switcher
from attaining a sufficiently low duty cycle if switching
frequency were maintained at 500kHz, so frequency is
reduced by about 5:1 when the feedback pin voltage drops
below 0.8V (see Frequency Foldback graph). This does
not affect operation with normal load conditions; one
simply sees a shift in switching frequency during start-up
as the output voltage rises.
In addition to lower switching frequency, the LT1956 also
operates at lower switch current limit when the feedback
pin voltage drops below 0.6V. Q2 in Figure 2 performs this
function by clamping the VC pin to a voltage less than its
normal 2.1V upper clamp level. This foldback current limit
greatly reduces power dissipation in the IC, diode and inductor during short-circuit conditions. External synchronization is also disabled to prevent interference with foldback operation. Again, it is nearly transparent to the user
under normal load conditions. The only loads that may be
affected are current source loads which maintain full load
current with output voltage less than 50% of final value. In
these rare situations the feedback pin can be clamped above
0.6V with an external diode to defeat foldback current limit.
Caution: clamping the feedback pin means that frequency
shifting will also be defeated, so a combination of high input voltage and dead shorted output may cause the LT1956
to lose control of current limit.
The internal circuitry which forces reduced switching
frequency also causes current to flow out of the feedback
pin when output voltage is low. The equivalent circuitry is
shown in Figure 2. Q1 is completely off during normal
operation. If the FB pin falls below 0.8V, Q1 begins to
conduct current and reduces frequency at the rate of
approximately 3.5kHz/µA. To ensure adequate frequency
foldback (under worst-case short-circuit conditions), the
external divider Thevinin resistance must be low enough
to pull 115µA out of the FB pin with 0.44V on the pin (RDIV
≤ 3.8k). The net result is that reductions in frequency and
current limit are affected by output voltage divider impedance. Although divider impedance is not critical, caution
should be used if resistors are increased beyond the
suggested values and short-circuit conditions will occur
1956f
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LT1956
VSW
TO FREQUENCY
SHIFTING
1.4V
ERROR
AMPLIFIER
+
–
L1
OUTPUT
5V
Q1
1.2V
R1
R4
2k
R3
1k
FB
+
C1
BUFFER
R2
Q2
TO SYNC CIRCUIT
VC
GND
1956 F02
Figure 2. Frequency and Current Limit Foldback
with high input voltage. High frequency pickup will increase and the protection accorded by frequency and
current foldback will decrease.
10mV/DIV
VOUT USING
22µF CERAMIC
OUTPUT
CAPACITOR
10mV/DIV
VOUT USING
100µF, 0.08Ω
TANTALUM
OUTPUT
CAPACITOR
CHOOSING THE INDUCTOR
For most applications, the output inductor will fall into the
range of 5µH to 30µH. Lower values are chosen to reduce
physical size of the inductor. Higher values allow more
output current because they reduce peak current seen by
the LT1956 switch, which has a 1.5A limit. Higher values
also reduce output ripple voltage.
When choosing an inductor you will need to consider
output ripple voltage, maximum load current, peak inductor current and fault current in the inductor. In addition,
other factors such as core and copper losses, allowable
component height, EMI, saturation and cost should also
be considered. The following procedure is suggested as a
way of handling these somewhat complicated and conflicting requirements.
Output Ripple Voltage
Figure 3 shows a comparison of output ripple voltage for
the LT1956 using either a tantalum or ceramic output
capacitor. It can be seen from Figure 3 that output ripple
voltage can be significantly reduced by using the ceramic
output capacitor; the significant decrease in output ripple
voltage is due to the very low ESR of ceramic capacitors.
VIN = 12V
VOUT = 5V
L = 15µH
1µs/DIV
1956 F03
Figure 3. LT1956 Output Ripple Voltage Waveforms.
Ceramic vs Tantalum Output Capacitors
Output ripple voltage is determined by ripple current
(ILP-P) through the inductor and the high frequency
impedance of the output capacitor. At high frequencies,
the impedance of the tantalum capacitor is dominated by
its effective series resistance (ESR).
Tantalum Output Capacitor
The typical method for reducing output ripple voltage
when using a tantalum output capacitor is to increase the
inductor value (to reduce the ripple current in the inductor). The following equations will help in choosing the
required inductor value to achieve a desirable output ripple
voltage level. If output ripple voltage is of less importance,
the subsequent suggestions in Peak Inductor and Fault
Current and EMI will additionally help in the selection of
the inductor value.
1956f
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Peak-to-peak output ripple voltage is the sum of a triwave
(created by peak-to-peak ripple current (ILP-P) times ESR)
and a square wave (created by parasitic inductance (ESL)
and ripple current slew rate). Capacitive reactance is
assumed to be small compared to ESR or ESL.
VRIPPLE = (ILP-P )(ESR) + (ESL)Σ
Peak Inductor Current and Fault Current
dI
dt
where:
ESR = equivalent series resistance of the output
capacitor
ESL = equivalent series inductance of the output
capacitor
dI/dt = slew rate of inductor ripple current = VIN/L
Peak-to-peak ripple current (ILP-P) through the inductor
and into the output capacitor is typically chosen to be
between 20% and 40% of the maximum load current. It is
approximated by:
ILP-P =
(VOUT )(VIN – VOUT )
(VIN )( f)(L)
(5)(12 − 5)
(12)(15 • 10–6 )(500 • 10–6 )
12
dI
= 106 • 0.8
Σ =
6
−
dt 15 • 10
(
To ensure that the inductor will not saturate, the peak inductor current should be calculated knowing the maximum
load current. An appropriate inductor should then be chosen. In addition, a decision should be made whether or not
the inductor must withstand continuous fault conditions.
If maximum load current is 0.5A, for instance, a 0.5A
inductor may not survive a continuous 2A overload condition. Dead shorts will actually be more gentle on the
inductor because the LT1956 has frequency and current
limit foldback.
Peak inductor and switch current can be significantly
higher than output current, especially with smaller inductors and lighter loads, so don’t omit this step. Powdered
Table 2
Example: with VIN = 12V, VOUT = 5V, L = 15µH, ESR =
0.080Ω and ESL = 10nH, output ripple voltage can be
approximated as follows:
ILP-P =
ceramic capacitor. Although this reduction of ESR removes a useful zero in the overall loop response, this zero
can be replaced by inserting a resistor (RC) in series with
the VC pin and the compensation capacitor CC. (See
Ceramic Capacitors in Applications Information.)
= 0.389 A
VENDOR/
PART NO.
VALUE
(µH)
IDC(MAX)
(Amps)
DCR
(Ohms)
HEIGHT
(mm)
UP1B-100
10
1.9
0.111
5.0
UP1B-220
22
1.2
0.254
5.0
UP2B-220
22
2.0
0.062
6.0
UP2B-330
33
1.7
0.092
6.0
UP1B-150
15
1.5
0.175
5.0
D01813P-153HC
15
1.5
0.170
5.0
D01813P-103HC
10
1.9
0.111
5.0
D53316P-223
22
1.6
0.207
5.1
D53316P-333
33
1.4
0.334
5.1
LP025060B-682
6.8
1.3
0.165
1.65
CDRH4D28-4R7
4.7
1.32
0.072
3.0
CDRH5D28-100
10
1.30
0.065
3.0
CDRH6D28-150
15
1.40
0.084
3.0
CDRH6D28-180
18
1.32
0.095
3.0
CDRH6D28-220
22
1.20
0.128
3.0
CDRH6D38-220
22
1.30
0.096
4.0
Coiltronics
Coilcraft
)( )
VRIPPLE = (0.389)(0.08) + 10 • 10 − 9 10 6 (0.8 )
= 0.031 + 0.008 = 39mVP-P
To reduce output ripple voltage further requires an increase in the inductor value with the trade-off being a
physically larger inductor with the possibility of increased
component height and cost.
Ceramic Output Capacitor
An alternative way to further reduce output ripple voltage
is to reduce the ESR of the output capacitor by using a
Sumida
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iron cores are forgiving because they saturate softly,
whereas ferrite cores saturate abruptly. Other core materials fall somewhere in between. The following formula
assumes continuous mode of operation, but errs only
slightly on the high side for discontinuous mode, so it can
be used for all conditions.
IPEAK = IOUT +
VOUT (VIN – VOUT )
ILP-P
= IOUT +
2
2 • VIN • f • L
EMI
Decide if the design can tolerate an “open” core geometry
like a rod or barrel, which have high magnetic field
radiation, or whether it needs a closed core like a toroid to
prevent EMI problems. This is a tough decision because
the rods or barrels are temptingly cheap and small and
there are no helpful guidelines to calculate when the
magnetic field radiation will be a problem.
Additional Considerations
After making an initial choice, consider additional factors
such as core losses and second sourcing, etc. Use the
experts in Linear Technology’s Applications department if
you feel uncertain about the final choice. They have
experience with a wide range of inductor types and can tell
you about the latest developments in low profile, surface
mounting, etc.
MAXIMUM OUTPUT LOAD CURRENT
Maximum load current for a buck converter is limited by
the maximum switch current rating (IP). The current rating
for the LT1956 is 1.5A. Unlike most current mode converters, the LT1956 maximum switch current limit does not
fall off at high duty cycles. Most current mode converters
suffer a drop off of peak switch current for duty cycles
above 50%. This is due to the effects of slope compensation required to prevent subharmonic oscillations in current mode converters. (For detailed analysis, see Application Note 19.)
The LT1956 is able to maintain peak switch current limit
over the full duty cycle range by using patented circuitry to
cancel the effects of slope compensation on peak switch
current without affecting the frequency compensation it
provides.
Maximum load current would be equal to maximum
switch current for an infinitely large inductor, but with
finite inductor size, maximum load current is reduced by
one half of peak-to-peak inductor current (ILP-P). The
following formula assumes continuous mode operation,
implying that the term on the right is less than one half
of␣ IP.
IOUT (MAX) Continuous Mode
= IP –
(VOUT + VF )(VIN – VOUT – VF )
ILP-P
= IP –
2
(2)(VIN )( f)(L)
For VOUT = 5V, VIN(MAX) = 8V, VF(DI) = 0.63V, f = 500kHz
and L = 10µH:
IOUT (MAX) = 1.5 –
(5 + 0.63)(8 – 5 – 0.63)
(2)(8)(500 • 103 )(10 • 10–6 )
= 1.5 – 0.17 = 1.33A
Note that there is less load current available at the higher
input voltage because inductor ripple current increases. At
VIN = 15V and using the same set of conditions:
IOUT (MAX) = 1.5 –
(5 + 0.63)(15 – 5 – 0.63)
(2)(15)(500 • 103 )(10 • 10–6 )
= 1.5 – 0.35 = 1.15A
To calculate peak switch current with a given set of
conditions, use:
ILP-P
2
V
( OUT + VF )(VIN – VOUT – VF )
+
(2)(VIN )( f)(L)
ISW(PEAK) = IOUT +
= IOUT
Reduced Inductor Value and Discontinuous Mode
If the smallest inductor value is of the most importance to
a converter design, in order to reduce inductor size/cost,
discontinuous mode may yield the smallest inductor
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solution. The maximum output load current in discontinuous mode, however, must be calculated and is defined
later in this section.
Discontinuous mode is entered when the output load
current is less than one-half of the inductor ripple current
(ILP-P). In this mode, inductor current falls to zero before
the next switch turn-on (see Figure 8). Buck converters
will be in discontinuous mode for output load current
given by:
IOUT Discontinous Mode
(V
+ V )( V – V
–V )
< OUT F IN OUT F
(2)( VIN )( f)(L)
The inductor value in a buck converter is usually chosen
large enough to keep inductor ripple current (ILP-P) low;
this is done to minimize output ripple voltage and maximize output load current. In the case of large inductor
values, as seen in the equation above, discontinuous
mode will be associated with “light loads.”
When choosing small inductor values, however, discontinuous mode will occur at much higher output load
currents. The limit to the smallest inductor value that can
be chosen is set by the LT1956 peak switch current (IP)
and the maximum output load current required given by:
IOUT(MAX) Discontinuous Mode
IP2
IP2 ( f)(L)(VIN )
=
=
2(ILP-P ) 2( VOUT + VF )(VIN – VOUT − VF )
Example: For VIN = 15V, VOUT = 5V, VF = 0.63V, f = 500kHz
and L = 4µH
IOUT (MAX) Discontinuous Mode
=
1.52 (500 • 103 )(4 • 10−6 )(15)
2(5 + 0.63)(15 – 5 – 0.63)
IOUT(MAX) Discontinuous Mode = 0.639A
What has been shown here is that if high inductor ripple
current and discontinuous mode operation can be tolerated, small inductor values can be used. If a higher output
load current is required, the inductor value must be
increased. If IOUT(MAX) no longer meets the discontinuous
mode criteria, use the IOUT(MAX) equation for continuous
mode; the LT1956 is designed to operate well in both
modes of operation, allowing a large range of inductor
values to be used.
SHORT-CIRCUIT CONSIDERATIONS
For a ground short-circuit fault on the regulated output,
the maximum input voltage for the LT1956 is typically
limited to 25V. If a greater input voltage is required,
increasing the resistance in series with the inductor may
suffice (see short-circuit calculations at the end of this
section). Alternatively, the 1.5A LT1766 can be used since
it is identical to the LT1956 but runs at a lower frequency
of 200kHz, allowing higher sustained input voltage capability during output short circuit.
The LT1956 is a current mode controller. It uses the VC
node voltage as an input to a current comparator which
turns off the output switch on a cycle-by-cycle basis as
peak switch current is reached. The internal clamp on the
VC node, nominally 2V, then acts as an output switch peak
current limit. This action becomes the switch current limit
specification. The maximum available output power is
then determined by the switch current limit.
A potential controllability problem could occur under
short-circuit conditions. If the power supply output is
short circuited, the feedback amplifier responds to the low
output voltage by raising the control voltage, VC, to its
peak current limit value. Ideally, the output switch would
be turned on, and then turned off as its current exceeded
the value indicated by VC. However, there is finite response
time involved in both the current comparator and turnoff
of the output switch. These result in a minimum on time
tON(MIN). When combined with the large ratio of VIN to
(VF + I • R), the diode forward voltage plus inductor I • R
voltage drop, the potential exists for a loss of control.
Expressed mathematically the requirement to maintain
control is:
f • tON ≤
VF + I • R
VIN
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where:
f = switching frequency
tON = switch minimum on time
VF = diode forward voltage
VIN = input voltage
I • R = inductor I • R voltage drop
If this condition is not observed, the current will not be
limited at IPK, but will cycle-by-cycle ratchet up to some
higher value. Using the nominal LT1956 clock frequency
of 500KHz, a VIN of 12V and a (VF + I • R) of say 0.7V, the
maximum tON to maintain control would be approximately
116ns, an unacceptably short time.
The solution to this dilemma is to slow down the oscillator
when the FB pin voltage is abnormally low thereby indicating some sort of short-circuit condition. Oscillator frequency is unaffected until FB voltage drops to about 2/3 of
its normal value. Below this point the oscillator frequency
decreases roughly linearly down to a limit of about 100kHz.
This lower oscillator frequency during short-circuit conditions can then maintain control with the effective minimum on time. Even with frequency foldback, however, the
LT1956 will not survive a permanent output short at the
absolute maximum voltage rating of VIN = 60V; this is
defined solely by internal semiconductor junction breakdown effects.
For the maximum input voltage allowed during an output
short to ground, the previous equation defining minimum
on-time can be used. Assuming VF (D1 catch diode) =
0.63V at 1A (short-circuit current is folded back to typical
switch current limit • 0.5), I (inductor) • DCR = 1A • 0.128
= 0.128V (L␣ =␣ CDRH6D28-22), typical f = 100kHz (folded
back) and typical minimum on-time = 300ns, the maximum allowable input voltage during an output short to
ground is typically:
VIN = (0.63V + 0.128V)/(100kHz • 300ns)
VIN(MAX) = 25V
Increasing the DCR of the inductor will increase the maximum VIN allowed during an output short to ground but will
also drop overall efficiency during normal operation.
Every time the converter wakes up from shutdown or
undervoltage lockout to begin switching, the output
capacitor may potentially be starting from 0V. This requires that the part obey the overall duty cycle demanded
by the loop, related to VIN and VOUT, as the output voltage
rises to its target value. It is recommended that for [VIN/
(VOUT + VF)] ratios > 4, a soft-start circuit should be used
to control the output capacitor charge rate during start-up
or during recovery from an output short circuit, thereby
adding additional control over peak inductor current. See
Buck Converter with Adjustable Soft-Start later in this
data sheet.
OUTPUT CAPACITOR
The LT1956 will operate with either ceramic or tantalum
output capacitors. The output capacitor is normally chosen by its effective series resistance (ESR), because this
is what determines output ripple voltage. The ESR range
for typical LT1956 applications using a tantalum output
capacitor is 0.05Ω to 0.2Ω. A typical output capacitor is an
AVX type TPS, 100µF at 10V, with a guaranteed ESR less
than 0.1Ω. This is a “D” size surface mount solid tantalum
capacitor. TPS capacitors are specially constructed and
tested for low ESR, so they give the lowest ESR for a given
volume. The value in microfarads is not particularly critical, and values from 22µF to greater than 500µF work well,
but you cannot cheat mother nature on ESR. If you find a
tiny 22µF solid tantalum capacitor, it will have high ESR,
and output ripple voltage will be terrible. Table 3 shows
some typical solid tantalum surface mount capacitors.
Table 3. Surface Mount Solid Tantalum Capacitor ESR
and Ripple Current
E CASE SIZE
ESR (MAX, Ω)
RIPPLE CURRENT (A)
AVX TPS, Sprague 593D
0.1 to 0.3
0.7 to 1.1
0.1 to 0.3
0.7 to 1.1
0.2 (typ)
0.5 (typ)
D CASE SIZE
AVX TPS, Sprague 593D
C CASE SIZE
AVX TPS
Unlike the input capacitor, RMS ripple current in the
output capacitor is normally low enough that ripple current rating is not an issue. The current waveform is
triangular with a typical value of 125mARMS. The formula
to calculate this is:
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Output capacitor ripple current (RMS):
IRIPPLE(RMS) =
0.29(VOUT )(VIN – VOUT )
(L)( f)(VIN )
Ceramic Capacitors
Ceramic capacitors are generally chosen for their good
high frequency operation, small size and very low ESR
(effective series resistance). Their low ESR reduces
output ripple voltage but also removes a useful zero in the
loop frequency response, common to tantalum capacitors. To compensate for this, a resistor RC can be placed
in series with the VC compensation capacitor CC. Care
must be taken however, since this resistor sets the high
frequency gain of the error amplifier, including the gain
at the switching frequency. If the gain of the error
amplifier is high enough at the switching frequency,
output ripple voltage (although smaller for a ceramic
output capacitor) may still affect the proper operation of
the regulator. A filter capacitor CF in parallel with the
RC/CC network is suggested to control possible ripple at
the VC pin. The LT1956 can be stabilized for VOUT = 5V at
1A using a 22µF ceramic output capacitor and VC component values of CC = 4700pF, RC␣ =␣ 4.7k and CF = 220pF.
INPUT CAPACITOR
Step-down regulators draw current from the input supply
in pulses. The rise and fall times of these pulses are very
fast. The input capacitor is required to reduce the voltage
ripple this causes at the input of LT1956 and force the
switching current into a tight local loop, thereby minimizing EMI. The RMS ripple current can be calculated from:
IRIPPLE(RMS)CIN = IOUT
VOUT (VIN – VOUT )
VIN2
Ceramic capacitors are ideal for input bypassing. At 500kHz
switching frequency, the energy storage requirement of
the input capacitor suggests that values in the range of
2.2µF to 10µF are suitable for most applications. If operation is required close to the minimum input required by the
output of the LT1956, a larger value may be required. This
is to prevent excessive ripple causing dips below the minimum operating voltage resulting in erratic operation.
Depending on how the LT1956 circuit is powered up you
may need to check for input voltage transients.
The input voltage transients may be caused by input
voltage steps or by connecting the LT1956 converter to an
already powered up source such as a wall adapter. The
sudden application of input voltage will cause a large
surge of current in the input leads that will store energy in
the parasitic inductance of the leads. This energy will
cause the input voltage to swing above the DC level of input
power source and it may exceed the maximum voltage
rating of input capacitor and LT1956.
The easiest way to suppress input voltage transients is to
add a small aluminum electrolytic capacitor in parallel with
the low ESR input capacitor. The selected capacitor needs
to have the right amount of ESR in order to critically
dampen the resonant circuit formed by the input lead
inductance and the input capacitor. The typical values of
ESR will fall in the range of 0.5Ω to 2Ω and capacitance will
fall in the range of 5µF to 50µF.
If tantalum capacitors are used, values in the 22µF to
470µF range are generally needed to minimize ESR and
meet ripple current and surge ratings. Care should be
taken to ensure the ripple and surge ratings are not
exceeded. The AVX TPS and Kemet T495 series are surge
rated. AVX recommends derating capacitor operating
voltage by 2 for high surge applications.
CATCH DIODE
Highest efficiency operation requires the use of a Schottky
type diode. DC switching losses are minimized due to its
low forward voltage drop, and AC behavior is benign due
to its lack of a significant reverse recovery time. Schottky
diodes are generally available with reverse voltage ratings
of up to 60V and even 100V, and are price competitive with
other types.
The use of so-called “ultrafast” recovery diodes is generally not recommended. When operating in continuous
mode, the reverse recovery time exhibited by “ultrafast”
diodes will result in a slingshot type effect. The power
1956f
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internal switch will ramp up VIN current into the diode in an
attempt to get it to recover. Then, when the diode has
finally turned off, some tens of nanoseconds later, the VSW
node voltage ramps up at an extremely high dV/dt, perhaps 5 to even 10V/ns ! With real world lead inductances,
the VSW node can easily overshoot the VIN rail. This can
result in poor RFI behavior and if the overshoot is severe
enough, damage the IC itself.
The suggested catch diode (D1) is an International Rectifier 10MQ060N Schottky. It is rated at 1.5A average
forward current and 60V reverse voltage. Typical forward
voltage is 0.63V at 1A. The diode conducts current only
during switch off time. Peak reverse voltage is equal to
regulator input voltage. Average forward current in normal
operation can be calculated from:
ID(AVG) = IOUT (1 – DC)
This formula will not yield values higher than 1.5A with
maximum load current of 1.5A. The only reason to
consider a larger diode is the worst-case condition of a
high input voltage and shorted output. With a shorted
condition, diode current will increase to a typical value of
2A, determined by peak switch current limit. This is safe
for short periods of time, but it would be prudent to check
with the diode manufacturer if continuous operation
under these conditions must be tolerated.
BOOST␣ PIN␣
For most applications, the boost components are a 0.1µF
capacitor and an MMSD914TI diode. The anode is typically connected to the regulated output voltage to generate
a voltage approximately VOUT above VIN to drive the output
stage. However, the output stage discharges the boost
capacitor during the on time of the switch. The output
driver requires at least 3V of headroom throughout this
period to keep the switch fully saturated. If the output
voltage is less than 3V, it is recommended that an alternate
boost supply is used. The boost diode can be connected to
the input, although, care must be taken to prevent the 2×
VIN boost voltage from exceeding the BOOST pin absolute
maximum rating. The additional voltage across the switch
driver also increases power loss, reducing efficiency. If
available, an independent supply can be used with a local
bypass capacitor.
A 0.1µF boost capacitor is recommended for most applications. Almost any type of film or ceramic capacitor is
suitable, but the ESR should be <1Ω to ensure it can be
fully recharged during the off time of the switch. The
capacitor value is derived from worst-case conditions of
1800ns on time, 42mA boost current and 0.7V discharge
ripple. The boost capacitor value could be reduced under
less demanding conditions, but this will not improve
circuit operation or efficiency. Under low input voltage and
low load conditions, a higher value capacitor will reduce
discharge ripple and improve start-up operation.
SHUTDOWN FUNCTION AND UNDERVOLTAGE
LOCKOUT
Figure 4 shows how to add undervoltage lockout (UVLO)
to the LT1956. Typically, UVLO is used in situations where
the input supply is current limited, or has a relatively high
source resistance. 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.
Threshold voltage for lockout is about 2.38V. A 5.5µA bias
current flows out of the pin at this threshold. The internally
generated current is used to force a default high state on
the shutdown pin if the pin is left open. When low shutdown current is not an issue, the error due to this current
can be minimized by making RLO 10k or less. If shutdown
current is an issue, RLO can be raised to 100k, but the error
due to initial bias current and changes with temperature
should be considered.
R LO = 10k to 100k (25k suggested)
R HI =
RLO ( VIN − 2.38 V )
2.38 V − R LO(5.5 µA)
VIN = minimum input voltage
Keep the connections from the resistors to the shutdown
pin short and make sure that interplane or surface capacitance to the switching nodes are minimized. If high
resistor values are used, the shutdown pin should be
1956f
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RFB
L1
LT1956
2.38V
IN
INPUT
OUTPUT
VSW
+
STANDBY
RHI
–
5.5µA
+
SHDN
C1
+
TOTAL
SHUTDOWN
RLO
C2
0.4V
–
GND
1956 F04
Figure 4. Undervoltage Lockout
bypassed with a 1000pF capacitor to prevent coupling
problems from the switch node. If hysteresis is desired in
the undervoltage lockout point, a resistor RFB can be
added to the output node. Resistor values can be calculated from:
R HI =
[
RLO VIN − 2.38 ( ∆V/ VOUT + 1) + ∆V
(
2.38 − RLO (5 .5µA )
R FB = (RHI ) VOUT /∆V
]
)
25k suggested for RLO
VIN = Input voltage at which switching stops as input
voltage descends to trip level
∆V = Hysteresis in input voltage level
Example: output voltage is 5V, switching is to stop if input
voltage drops below 12V and should not restart unless
input rises back to 13.5V. ∆V is therefore 1.5V and
VIN␣ =␣ 12V. Let RLO = 25k.
[
)
2.38 – 25k(5.5µA )
25k (10.41)
=
= 116k
R HI =
(
]
25k 12 − 2.38 1.5 / 5 + 1 + 1.5
2.24
R FB = 116k 5 / 1.5 = 387k
(
)
SYNCHRONIZING
The SYNC input must pass from a logic level low, through
the maximum synchronization threshold with a duty cycle
between 10% and 90%. The input can be driven directly
from a logic level output. The synchronizing range is equal
to initial operating frequency up to 700kHz. This means
that minimum practical sync frequency is equal to the
worst-case high self-oscillating frequency (570kHz), not
the typical operating frequency of 500kHz. Caution should
be used when synchronizing above 662kHz because at
higher sync frequencies the amplitude of the internal slope
compensation used to prevent subharmonic switching is
reduced. This type of subharmonic switching only occurs
at input voltages less than twice output voltage. Higher
inductor values will tend to eliminate this problem. See
Frequency Compensation section for a discussion of an
entirely different cause of subharmonic switching before
assuming that the cause is insufficient slope compensation. Application Note 19 has more details on the theory
of slope compensation.
At power-up, when VC is being clamped by the FB pin (see
Figure 2, Q2), the sync function is disabled. This allows the
frequency foldback to operate in the shorted output condition. During normal operation, switching frequency is
controlled by the internal oscillator until the FB pin reaches
0.8V, after which the SYNC pin becomes operational. If no
synchronization is required, this pin should be connected
to ground.
1956f
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LAYOUT CONSIDERATIONS
LT1956
As with all high frequency switchers, when considering
layout, care must be taken in order to achieve optimal
electrical, thermal and noise performance. For maximum
efficiency, switch rise and fall times are typically in the
nanosecond range. To prevent noise both radiated and
conducted, the high speed switching current path, shown
in Figure 5, must be kept as short as possible. This is
implemented in the suggested layout of Figure 6. Shortening this path will also reduce the parasitic trace inductance
of approximately 25nH/inch. At switch off, this parasitic
inductance produces a flyback spike across the LT1956
switch. When operating at higher currents and input
voltages, with poor layout, this spike can generate voltages across the LT1956 that may exceed its absolute
maximum rating. A ground plane should always be used
under the switcher circuitry to prevent interplane coupling
and overall noise.
L1
5V
VIN
C3
HIGH
FREQUENCY
CIRCULATING
PATH
D1
C1
LOAD
1956 F05
Figure 5. High Speed Switching Path
The VC and FB components should be kept as far away as
possible from the switch and boost nodes. The LT1956
pinout has been designed to aid in this. The ground for
these components should be separated from the switch
current path. Failure to do so will result in poor stability or
subharmonic like oscillation.
CONNECT TO
GROUND PLANE
GND
L1
C1
MINIMIZE LT1956
C3-D1 LOOP
GND
D2
D1
VOUT
C2
GND
GND
SHDN
KELVIN SENSE
VOUT
SW
VIN
C3
SYNC
LT1956
FB
BOOST
VC
R2
R1 CFB
BIAS
VIN
FOR THE FE PACKAGE,
SOLDER THE EXPOSED
PAD TO THE COPPER
GROUND PLANE
UNDERNEATH THE DEVICE
GND
CF
GND
RC
PLACE FEEDTHROUGH AROUND
GROUND PINS (4 CORNERS) FOR
GOOD THERMAL CONDUCTIVITY
CC
KEEP FB AND VC COMPONENTS
AWAY FROM HIGH FREQUENCY,
HIGH CURRENT COMPONENTS
1956 F06
Figure 6. Suggested Layout
1956f
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Board layout also has a significant effect on thermal resistance. For the GN package, Pins 1, 8, 9 and 16, GND, are
a continuous copper plate that runs under the LT1956 die.
This is the best thermal path for heat out of the package.
Reducing the thermal resistance from Pins 1, 8, 9 and 16
onto the board will reduce die temperature and increase
the power capability of the LT1956. This is achieved by
providing as much copper area as possible around these
pins. Adding multiple solder filled feedthroughs under and
around these four corner pins to the ground plane will also
help. Similar treatment to the catch diode and coil terminations will reduce any additional heating effects. For the
FE package, the exposed pad should be soldered to the
copper ground plane underneath the device.
PARASITIC RESONANCE
Resonance or “ringing” may sometimes be seen on the
switch node (see Figure 7). Very high frequency ringing
following switch rise time is caused by switch/diode/input
capacitor lead inductance and diode capacitance. Schottky diodes have very high “Q” junction capacitance that
can ring for many cycles when excited at high frequency.
If total lead length for the input capacitor, diode and switch
path is 1 inch, the inductance will be approximately 25nH.
At switch off, this will produce a spike across the NPN
output device in addition to the input voltage. At higher
currents this spike can be in the order of 10V to 20V or
higher with a poor layout, potentially exceeding the absolute max switch voltage. The path around switch, catch
diode and input capacitor must be kept as short as
possible to ensure reliable operation. When looking at this,
SW RISE
SW FALL
a >100MHz oscilloscope must be used, and waveforms
should be observed on the leads of the package. This
switch off spike will also cause the SW node to go below
ground. The LT1956 has special circuitry inside which
mitigates this problem, but negative voltages over 0.8V
lasting longer than 10ns should be avoided. Note that
100MHz oscilloscopes are barely fast enough to see the
details of the falling edge overshoot in Figure 7.
A second, much lower frequency ringing is seen during
switch off time if load current is low enough to allow the
inductor current to fall to zero during part of the switch off
time (see Figure 8). Switch and diode capacitance resonate
with the inductor to form damped ringing at 1MHz to 10
MHz. This ringing is not harmful to the regulator and it has
not been shown to contribute significantly to EMI. Any
attempt to damp it with a resistive snubber will degrade
efficiency.
THERMAL CALCULATIONS
Power dissipation in the LT1956 chip comes from four
sources: switch DC loss, switch AC loss, boost circuit
current, and input quiescent current. The following formulas show how to calculate each of these losses. These
formulas assume continuous mode operation, so they
should not be used for calculating efficiency at light load
currents.
Switch loss:
PSW =
RSW (IOUT ) ( VOUT )
+ tEFF (1/ 2)(IOUT )( VIN)( f)
VIN
10V/DIV
SWITCH NODE
VOLTAGE
0.2A/DIV
INDUCTOR
CURRENT AT
IOUT = 0.1A
2
2V/DIV
50ns/DIV
1956 F07
Figure 7. Switch Node Resonance
VIN = 25V
VOUT = 5V
L = 15µH
500ns/DIV
1956 F08
Figure 8. Discontinuous Mode Ringing
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Boost current loss:
PDIODE =
VOUT2 (IOUT / 36)
PBOOST =
VIN
VF = Forward voltage of diode (assume 0.63V at 1A)
Quiescent current loss:
PDIODE =
PQ = VIN (0.0015) + VOUT (0.003)
PINDUCTOR = (ILOAD)(LDCR)
LDCR = inductor DC resistance (assume 0.1Ω)
PINDUCTOR = (1)(0.1) = 0.1W
Example: with VIN = 12V, VOUT = 5V and IOUT = 1A:
PSW
(
)
(
57 •10 −9 (1/ 2)(1)(12 ) 500 •10 3
12
= 0.125 + 0.171 = 0.296W
)
(5) (1 / 36) = 0.058W
2
PBOOST =
(0.63 )(12 – 5 )(1)
= 0.37W
12
Notice that the catch diode’s forward voltage contributes
a significant loss in the overall system efficiency. A larger,
low VF diode can improve efficiency by several percent.
RSW = switch resistance (≈ 0.3) hot
tEFF = effective switch current/voltage overlap time
= (tr + tf + tIr + tIf)
tr = (VIN/1.2)ns
tf = (VIN/1.7)ns
tIr = tIf = (IOUT/0.05)ns
f = switch frequency
2
0.3)(1) (5)
(
=
+
( VF )( VIN – VOUT )(ILOAD )
VIN
12
PQ = 12(0.0015) + 5(0.003) = 0.033W
Total power dissipation in the IC is given by:
PTOT = PSW + PBOOST + PQ
= 0.296W + 0.058W + 0.033W = 0.39W
Thermal resistance for the LT1956 packages is influenced
by the presence of internal or backside planes.
SSOP (GN16) Package: With a full plane under the GN16
package, thermal resistance will be about 85°C/W.
TSSOP (Exposed Pad) Package: With a full plane under the
TSSOP package, thermal resistance (θJA) will be about
45°C/W.
To calculate die temperature, use the proper thermal
resistance (θJA) number for the desired package an add in
worst-case ambient temperature:
TJ = TA + (θJA • PTOT)
When estimating ambient, remember the nearby catch
diode and inductor will also be dissipating power.
Typical thermal resistance of the board is 10°C/W. Taking
the catch diode and inductor power dissipation into account and using the example calculations for LT1956 dissipation, the LT1956 die temperature will be estimated as:
TJ = TA + (θJA • PTOT) + (10 • [PDIODE + PINDUCTOR])
With the GN16 package (θJA = 85°C/W), at an ambient
temperature of 70°C:
TJ = 70 + (85 • 0.39) + (10 • 0.47) = 108°C
With the TSSOP package (θJA = 45°C/W) at an ambient
temperature of 70°C:
TJ = 70 + (45 • 0.37) + (10 • 0.47) = 91°C
Die temperature can peak for certain combinations of
VIN, VOUT and load current. While higher VIN gives greater
switch AC losses, quiescent and catch diode losses, a
lower VIN may generate greater losses due to switch DC
losses. In general, the maximum and minimum VIN levels
should be checked with maximum typical load current for
calculation of the LT1956 die temperature. If a more
accurate die temperature is required, a measurement of
the SYNC pin resistance (to GND) can be used. The SYNC
pin resistance can be measured by forcing a voltage no
greater than 0.5V at the pin and monitoring the pin
current over temperature in a oven. This should be done
with minimal device power (low VIN and no switching
[VC = 0V]) in order to calibrate SYNC pin resistance with
ambient (oven) temperature.
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Note: Some of the internal power dissipation in the IC, due
to BOOST pin voltage, can be transferred outside of the IC
to reduce junction temperature by increasing the voltage
drop in the path of the boost diode D2 (see Figure 9). This
reduction of junction temperature inside the IC will allow
higher ambient temperature operation for a given set of
conditions. BOOST pin circuitry dissipates power given by:
PDISS (BOOST Pin) =
VOUT • (ISW / 36) • VC2
VIN
Typically, VC2 (the boost voltage across the capacitor C2)
equals VOUT. This is because diodes D1 and D2 can be
considered almost equal, where:
VC2 = VOUT – VF(D2) – [–VF(D1)] = VOUT.
Hence, the equation for boost circuitry power dissipation
given in the previous Thermal Calculations section, is
stated as:
PDISS(BOOST)
VOUT • (ISW / 36) • VOUT
=
VIN
Here it can be seen that boost power dissipation increases
as the square of VOUT. It is possible, however, to reduce
VC2 below VOUT to save power dissipation by increasing
the voltage drop in the path of D2. Care should be taken
that VC2 does not fall below the minimum 3.3V boost
voltage required for full saturation of the internal power
switch. For output voltages of 5V, VC2 is approximately 5V.
During switch turn on, VC2 will fall as the boost capacitor
C2 is discharged by the BOOST pin. In the previous BOOST
Pin section, the value of C2 was designed for a 0.7V droop
in VC2 (= VDROOP). Hence, an output voltage as low as 4V
would still allow the minimum 3.3V for the boost function
using the C2 capacitor calculated.
If a target output voltage of 12V is required, however, an
excess of 8V is placed across the boost capacitor which is
not required for the boost function but still dissipates
additional power.
What is required is a voltage drop in the path of D2 to
achieve minimal power dissipation while still maintaining
minimum boost voltage across C2.
A zener, D4, placed in series with D2 (see Figure 9), drops
voltage to C2.
Example:
The BOOST pin power dissipation for a 20V input to 12V
output conversion at 1A is given by:
PBOOST =
12 • (1 / 36) • 12
= 0.2W
20
If a 7V zener is placed in series with D2, then power
dissipation becomes:
PBOOST =
12 • (1 / 36) • 5
= 0.084 W
20
For an FE package with thermal resistance of 45°C/W,
ambient temperature savings would be:
T (ambient) savings = 0.116W • 45°C/W = 5°C
For a GN package with thermal resistance of 85°C/W,
ambient temperature savings would be:
T (ambient) savings = 0.116W • 85°C/W = 10°C
The 7V zener should be sized for excess of 0.116W
operation. The tolerances of the zener should be considered to ensure minimum VBOOST exceeds 3.3V + VDROOP.
D2
D4
D2
C2
BOOST
VIN
VIN
C3
LT1956
L1
VOUT
SW
SHDN
BIAS
SYNC
FB
R1
VC
GND
RC
D1
+
C1
R2
CF
CC
1956 F09
Figure 9. BOOST Pin, Diode Selection
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Input Voltage vs Operating Frequency Considerations
The absolute maximum input supply voltage for the LT1956
is specified at 60V. This is based on internal semiconductor junction breakdown effects. The practical maximum
input supply voltage for the LT1956 may be less than 60V
due to internal power dissipation or switch minimum on
time considerations.
For the extreme case of an output short-circuit fault to
ground, see the section Short-Circuit Considerations.
A detailed theoretical basis for estimating internal power
dissipation is given in the Thermal Calculations section.
This will allow a first pass check of whether an application’s
maximum input voltage requirement is suitable for the
LT1956. Be aware that these calculations are for DC input
voltages and that input voltage transients as high as 60V
are possible if the resulting increase in internal power
dissipation is of insufficient time duration to raise die
temperature significantly. For the FE package, this means
high voltage transients on the order of hundreds of milliseconds are possible. If LT1956 (FE package) thermal
calculations show power dissipation is not suitable for the
given application, the LT1766 (FE package) is a recommended alternative since it is identical to the LT1956 but
runs cooler at 200kHz.
Switch minimum on time is the other factor that may limit
the maximum operational input voltage for the LT1956 if
pulse-skipping behavior is not allowed. For the LT1956,
pulse-skipping may occur for VIN/(VOUT + VF) ratios > 4.
(VF = Schottky diode D1 forward voltage drop, Figure 5.)
If the LT1766 is used, the ratio increases to 10. Pulseskipping is the regulator’s way of missing switch pulses to
maintain output voltage regulation. Although an increase
in output ripple voltage can occur during pulse-skipping,
a ceramic output capacitor can be used to keep ripple
voltage to a minimum (see output ripple voltage comparison for tantalum vs ceramic output capacitors, Figure 3).
FREQUENCY COMPENSATION
Before starting on the theoretical analysis of frequency
response, the following should be remembered—the worse
the board layout, the more difficult the circuit will be to
stabilize. This is true of almost all high frequency analog
circuits, read the Layout Considerations section first.
Common layout errors that appear as stability problems
are distant placement of input decoupling capacitor and/
or catch diode, and connecting the VC compensation to a
ground track carrying significant switch current. In addition, the theoretical analysis considers only first order
non-ideal component behavior. For these reasons, it is
important that a final stability check is made with production layout and components.
The LT1956 uses current mode control. This alleviates
many of the phase shift problems associated with the
inductor. The basic regulator loop is shown in Figure 10.
The LT1956 can be considered as two gm blocks, the error
amplifier and the power stage.
Figure 11 shows the overall loop response. At the VC pin,
the frequency compensation components used are:
RC = 2.2k, CC = 0.022µF and CF = 220pF. The output
capacitor used is a 100µF, 10V tantalum capacitor with
typical ESR of 100mΩ.
The ESR of the tantalum output capacitor provides a useful
zero in the loop frequency response for maintaining stability. This ESR, however, contributes significantly to the
ripple voltage at the output (see Output Ripple Voltage in
the Applications Information section). It is possible to
reduce capacitor size and output ripple voltage by replacing the tantalum output capacitor with a ceramic output
capacitor because of its very low ESR. The zero provided
by the tantalum output capacitor must now be reinserted
back into the loop. Alternatively, there may be cases
where, even with the tantalum output capacitor, an additional zero is required in the loop to increase phase margin
for improved transient response.
A zero can be added into the loop by placing a resistor (RC)
at the VC pin in series with the compensation capacitor, CC,
or by placing a capacitor (CFB) between the output and the
FB pin.
When using RC, the maximum value has two limitations.
First, the combination of output capacitor ESR and RC may
stop the loop rolling off altogether. Second, if the loop gain
is not rolled off sufficiently at the switching frequency,
output ripple will perturb the VC pin enough to cause
unstable duty cycle switching similar to subharmonic
1956f
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80
180
LT1956
60
SW
CFB
40
R1
FB
TANTALUM
–
+
RO
200k
1.22V
ESR
RLOAD
CERAMIC
ESL
+
C1
VC
120
20
90
PHASE
0
60
–20
30
PHASE (DEG)
ERROR
AMPLIFIER
gm =
2000µmho
GND
150
GAIN
OUTPUT
GAIN (dB)
CURRENT MODE
POWER STAGE
gm = 2mho
C1
R2
RC
–40
CF
CC
1956 F10
Figure 10. Model for Loop Response
oscillations. If needed, an additional capacitor (CF) can be
added across the RC/CC network from the VC pin to ground
to further suppress VC ripple voltage.
With a tantalum output capacitor, the LT1956 already
includes a resistor (RC) and filter capacitor (CF) at the VC
pin (see Figures 10 and 11) to compensate the loop over
the entire VIN range (to allow for stable pulse skipping for
high VIN-to-VOUT ratios ≥ 4). A ceramic output capacitor
can still be used with a simple adjustment to the resistor
RC for stable operation (see Ceramic Capacitors section
for stabilizing LT1956). If additional phase margin is
required, a capacitor (CFB) can be inserted between the
output and FB pin but care must be taken for high output
voltage applications. Sudden shorts to the output can
create unacceptably large negative transients on the FB
pin.
For VIN-to-VOUT ratios < 4, higher loop bandwidths are
possible by readjusting the frequency compensation components at the VC pin.
When checking loop stability, the circuit should be operated over the application’s full voltage, current and temperature range. Proper loop compensation may be obtained
by empirical methods as described in Application Notes 19
and 76.
10
100
1k
10k
100k
FREQUENCY (Hz)
VIN = 12V
RC = 2.2k
VOUT = 5V
CC = 22nF
ILOAD = 500mA
CF = 220pF
COUT = 100µF, 10V, 0.1Ω
0
1M
1956 F11
Figure 11. Overall Loop Response
CONVERTER WITH BACKUP OUTPUT REGULATOR
In systems with a primary and backup supply, for example, a battery powered device with a wall adapter input,
the output of the LT1956 can be held up by the backup
supply with the LT1956 input disconnected. In this condition, the SW pin will source current into the VIN pin. If the
SHDN pin is held at ground, only the shut down current of
25µA will be pulled via the SW pin from the second supply.
With the SHDN pin floating, the LT1956 will consume its
quiescent operating current of 1.5mA. The VIN pin will also
source current to any other components connected to the
input line. If this load is greater than 10mA or the input
could be shorted to ground, a series Schottky diode must
be added, as shown in Figure 12. With these safeguards,
the output can be held at voltages up to the VIN absolute
maximum rating.
BUCK CONVERTER WITH ADJUSTABLE SOFT-START
Large capacitive loads or high input voltages can cause
high input currents at start-up. Figure 13 shows a circuit
that limits the dv/dt of the output at start-up, controlling
the capacitor charge rate. The buck converter is a typical
configuration with the addition of R3, R4, CSS and Q1.
As the output starts to rise, Q1 turns on, regulating switch
1956f
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MMSD914TI
D3
10MQ060N
REMOVABLE
INPUT
C2
0.1µF
BOOST
VIN
SW
LT1956
R3
54k
L1
18µH
5V, 1A
BIAS
R1
15.4k
SHDN
FB
SYNC
GND
R4
25k
D1
10MQ060N
VC
C3
2.2µF
R2
4.99k
+
ALTERNATE
SUPPLY
C1
100µF
10V
CF
220pF
RC
2.2k
CC
0.022µF
1956 F12
Figure 12. Dual Source Supply with 25µA Reverse Leakage
D2
MMSD914TI
BOOST
INPUT
12V
C3
2.2µF
CERAMIC
C2
0.1µF
BIAS
VIN
L1
18µH
SW
D1
LT1956
SHDN
SYNC GND
+
R1
15.4k
FB
R2
4.99k
VC
Q1
RC
2.2k
CC
0.022µF
C1
100µF
OUTPUT
5V
1A
CF
220pF
R3
2k
CSS
15nF
1766 F13
R4
47k
Figure 13. Buck Converter with Adjustable Soft-Start
current via the VC pin to maintain a constant dv/dt at the
output. Output rise time is controlled by the current
through CSS defined by R4 and Q1’s VBE. Once the output
is in regulation, Q1 turns off and the circuit operates
normally. R3 is transient protection for the base of Q1.
RiseTime =
(R4)(CSS )(VOUT )
VBE
Using the values shown in Figure 10,
Rise Time =
(47 • 103 )(15 • 10–9 )(5) = 5ms
0.7
The ramp is linear and rise times in the order of 100ms are
possible. Since the circuit is voltage controlled, the ramp
rate is unaffected by load characteristics and maximum
output current is unchanged. Variants of this circuit can be
used for sequencing multiple regulator outputs.
DUAL POLARITY OUTPUT CONVERTER
The circuit in Figure 14a generates both positive and
negative 5V outputs with all components under 3mm
height. The topology for the 5V output is a standard buck
converter. The –5V output uses a second inductor L2,
diode D3 and output capacitor C6. The capacitor C4
1956f
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D2
MMSD914TI
C2
0.1µF
L1*
15µH
BOOST
VIN
9V TO 12V
(TRANSIENTS
TO 36V)
VOUT1**
5V
SW
VIN
LT1956
R1
15.4k
SHDN
C3
2.2µF
50V
CERAMIC
SYNC
C5
10µF
6.3V
CER
+
FB
GND
R2
4.99k
VC
RC
2.2k
CC
3300pF
CF
220pF
D1
B0540W
GND
C4
10µF
*SUMIDA CDRH4D28-150
6.3V
**SEE FIGURE 14c FOR VOUT1, VOUT2
CER
LOAD CURRENT RELATIONSHIP
†
IF LOAD CAN GO TO ZERO, AN OPTIONAL
PRELOAD OF 500Ω CAN BE
USED TO IMPROVE REGULATION
+
C6
10µF
6.3V CER
L2*
+
VOUT2**†
–5V
D3
B0540W
1956 F14a
500
5.30
450
5.25
400
5.20
100
80
250
200
150
5.05
VOUT1 LOAD CURRENT
250mA
5.00
4.95
EFFICIENCY (%)
300
VOUT1 LOAD CURRENT
500mA
5.10
60
50
40
30
100
4.85
20
50
4.80
10
0
4.75
600
400
200
VOUT1 LOAD CURRENT (mA)
800
0
100
200
300
400
500
VOUT2 LOAD CURRENT (mA)
1956 F15b
Figure 14b. VOUT2 (–5V) Maximum
Allowable Load Current vs VOUT1
(5V) Load Current
600
1956 F14c
Figure 14c. VOUT2 (–5V) Output
Voltage vs Load Current
couples energy to L2 and ensures equal voltages across
L2 and L1 during steady state. Instead of using a transformer for L1 and L2, uncoupled inductors were used
because they require less height than a single transformer,
can be placed separately in the circuit layout for optimized
space savings and reduce overall cost. This is true even
when the uncoupled inductors are sized (twice the value of
inductance of the transformer) in order to keep ripple
current comparable to the transformer solution. If a single
VOUT1 LOAD CURRENT
250mA
70
4.90
0
VOUT1 LOAD CURRENT
750mA
90
VOUT1 LOAD CURRENT
750mA
5.15
350
|VOUT2| (V)
VOUT2 MAXIMUM LOAD CURRENT (mA)
Figure 14a. Dual Polarity Output Converter
0
0
100
300
400
200
VOUT2 LOAD CURRENT (mA)
500
1956 F14d
Figure 14d. Dual Polarity Output
Converter Efficiency
transformer becomes available to provide a better height/
cost solution, refer to the dual output SEPIC circuit description in Design Note 100 for correct transformer
connection.
During switch on-time, in steady state, the voltage across
both L1 and L2 is positive and equal; with energy (and
current) ramping up in each inductor. The current in L2 is
provided by the coupling capacitor C4. During switch offtime, current ramps downward in each inductor. The
1956f
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current in L2 and C4 flows via the catch diode D3, charging
the negative output capacitor C6. If the negative output is
not loaded enough, it can go severely unregulated (become more negative). Figure 14b shows the maximum
allowable –5V output load current (vs load current on the
5V output) that will maintain the –5V output within 3%
tolerance. Figure 14c shows the –5V output voltage regulation vs its own load current when plotted for three
separate load currents on the 5V output. The efficiency of
the dual output converter circuit shown in Figure 14a is
given in Figure 14d.
POSITIVE-TO-NEGATIVE CONVERTER
The circuit in Figure 15 is a positive-to-negative topology
using a grounded inductor. It differs from the standard
approach in the way the IC chip derives its feedback signal
because the LT1956 accepts only positive feedback signals. The ground pin must be tied to the regulated negative
output. A resistor divider to the FB pin, then provides the
proper feedback voltage for the chip.
The following equation can be used to calculate maximum
load current for the positive-to-negative converter:
D2
MMSD914TI
C2
0.1µF
VIN
12V
C3
2.2µF
25V
BOOST
L1*
7µH
SW
VIN
R1
36.5k
LT1956
GND
VC
FB
CC
CF
RC
D1
10MQO60N
+
R2
4.12k
C1
100µF
20V TANT
OUTPUT**
–12V, 0.25A
* INCREASE L1 TO 10µH OR 18µH FOR HIGHER CURRENT APPLICATIONS.
SEE APPLICATIONS INFORMATION
** MAXIMUM LOAD CURRENT DEPENDS ON MINIMUM INPUT VOLTAGE
AND INDUCTOR SIZE. SEE APPLICATIONS INFORMATION
Figure 15. Positive-to-Negative Converter
1956 F15
IMAX

(VIN )(VOUT ) 
IP – 2(V
(VOUT )(VIN – 0.3)
OUT + VIN )(f)(L)

=
(VOUT + VIN – 0.3)(VOUT + VF )
IP = maximum rated switch current
VIN = minimum input voltage
VOUT = output voltage
VF = catch diode forward voltage
0.3 = switch voltage drop at 1.5A
Example: with VIN(MIN) = 5.5V, VOUT = 12V, L = 15µH,
VF = 0.63V, IP = 1.5A: IMAX = 0.36A.
INDUCTOR VALUE
The criteria for choosing the inductor is typically based on
ensuring that peak switch current rating is not exceeded.
This gives the lowest value of inductance that can be used,
but in some cases (lower output load currents) it may give
a value that creates unnecessarily high output ripple
voltage.
The difficulty in calculating the minimum inductor size
needed is that you must first decide whether the switcher
will be in continuous or discontinuous mode at the critical
point where switch current reaches 1.5A. The first step is
to use the following formula to calculate the load current
above which the switcher must use continuous mode. If
your load current is less than this, use the discontinuous
mode formula to calculate minimum inductor needed. If
load current is higher, use the continuous mode formula.
Output current where continuous mode is needed:
ICONT >
( VIN )2 (IP )2
4( VIN + VOUT )( VIN + VOUT + VF )
Minimum inductor discontinuous mode:
LMIN =
2( VOUT )(IOUT )
( f)(IP )2
1956f
25
LT1956/LT1956-5
U
PACKAGE DESCRIPTIO
Minimum inductor continuous mode:
LMIN =
(VIN )(VOUT )

 (V
+ VF ) 
2(f)(VIN + VOUT )IP – IOUT  1 + OUT



VIN

For a 12V to –12V converter using the LT1956 with peak
switch current of 1.5A and a catch diode of 0.63V:
ICONT >
(12)2 (1.5)2
= 0.370 A
4(12 + 12)(12 + 12 + 0.63)
For a load current of 0.25A, this says that discontinuous
mode can be used and the minimum inductor needed is
found from:
2(12)(0.25)
LMIN =
= 5.3µH
(500 • 103 )(1.5)2
In practice, the inductor should be increased by about
30% over the calculated minimum to handle losses and
variations in value. This suggests a minimum inductor of
7µH for this application.
Ripple Current in the Input and Output Capacitors
Positive-to-negative converters have high ripple current
in the input capacitor. For long capacitor lifetime, the
RMS value of this current must be less than the high
frequency ripple current rating of the capacitor. The
following formula will give an approximate value for RMS
ripple current. This formula assumes continuous mode
and large inductor value. Small inductors will give somewhat higher ripple current, especially in discontinuous
mode. The exact formulas are very complex and appear
in Application Note 44, pages 29 and 30. For our purposes here I have simply added a fudge factor (ff). The
value for ff is about 1.2 for higher load currents and L
≥15µH. It increases to about 2.0 for smaller inductors at
lower load currents.
Capacitor IRMS = ( ff)(IOUT )
ff = 1.2 to 2.0
VOUT
VIN
The output capacitor ripple current for the positive-tonegative converter is similar to that for a typical buck
regulator—it is a triangular waveform with peak-to-peak
value equal to the peak-to-peak triangular waveform of the
inductor. The low output ripple design in Figure 14 places
the input capacitor between VIN and the regulated negative
output. This placement of the input capacitor significantly
reduces the size required for the output capacitor (versus
placing the input capacitor between VIN and ground).
The peak-to-peak ripple current in both the inductor and
output capacitor (assuming continuous mode) is:
IP-P =
DC • VIN
f •L
DC = Duty Cycle =
ICOUT (RMS) =
VOUT + VF
VOUT + VIN + VF
IP-P
12
The output ripple voltage for this configuration is as low as
the typical buck regulator based predominantly on the
inductor’s triangular peak-to-peak ripple current and the
ESR of the chosen capacitor (see Output Ripple Voltage in
Applications Information).
Diode Current
Average diode current is equal to load current. Peak diode
current will be considerably higher.
Peak diode current:
Continuous Mode =
(V + V )
( VIN )( VOUT )
IOUT IN OUT +
VIN
2(L)( f)( VIN + VOUT )
Discontinuous Mode =
2(IOUT )( VOUT )
(L)( f)
Keep in mind that during start-up and output overloads,
average diode current may be much higher than with
normal loads. Care should be used if diodes rated less than
1A are used, especially if continuous overload conditions
must be tolerated.
1956f
26
LT1956/LT1956-5
U
PACKAGE DESCRIPTIO
FE Package
16-Lead Plastic TSSOP (4.4mm)
(Reference LTC DWG # 05-08-1663)
Exposed Pad Variation BB
4.90 – 5.10*
(.193 – .201)
3.58
(.141)
3.58
(.141)
16 1514 13 12 1110
6.60 ±0.10
9
2.94
(.116)
4.50 ±0.10
SEE NOTE 4
2.94 6.40
(.116) BSC
0.45 ±0.05
1.05 ±0.10
0.65 BSC
1 2 3 4 5 6 7 8
RECOMMENDED SOLDER PAD LAYOUT
1.10
(.0433)
MAX
4.30 – 4.50*
(.169 – .177)
0° – 8°
0.09 – 0.20
(.0036 – .0079)
0.45 – 0.75
(.018 – .030)
NOTE:
1. CONTROLLING DIMENSION: MILLIMETERS
MILLIMETERS
2. DIMENSIONS ARE IN
(INCHES)
3. DRAWING NOT TO SCALE
0.65
(.0256)
BSC
0.195 – 0.30
(.0077 – .0118)
0.05 – 0.15
(.002 – .006)
FE16 (BB) TSSOP 0203
4. RECOMMENDED MINIMUM PCB METAL SIZE
FOR EXPOSED PAD ATTACHMENT
*DIMENSIONS DO NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.150mm (.006") PER SIDE
1956f
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.
27
LT1956/LT1956-5
U
PACKAGE DESCRIPTIO
GN Package
16-Lead Plastic SSOP (Narrow .150 Inch)
(Reference LTC DWG # 05-08-1641)
.189 – .196*
(4.801 – 4.978)
.045 ±.005
.009
(0.229)
REF
16 15 14 13 12 11 10 9
.254 MIN
.150 – .165
.229 – .244
(5.817 – 6.198)
.0165 ± .0015
.150 – .157**
(3.810 – 3.988)
.0250 TYP
RECOMMENDED SOLDER PAD LAYOUT
1
.015 ± .004
× 45°
(0.38 ± 0.10)
.007 – .0098
(0.178 – 0.249)
2 3
.053 – .068
(1.351 – 1.727)
4
5 6
7
8
.004 – .0098
(0.102 – 0.249)
0° – 8° TYP
.016 – .050
(0.406 – 1.270)
.008 – .012
(0.203 – 0.305)
NOTE:
1. CONTROLLING DIMENSION: INCHES
INCHES
2. DIMENSIONS ARE IN
(MILLIMETERS)
3. DRAWING NOT TO SCALE
*DIMENSION DOES NOT INCLUDE MOLD FLASH. MOLD FLASH
SHALL NOT EXCEED 0.006" (0.152mm) PER SIDE
**DIMENSION DOES NOT INCLUDE INTERLEAD FLASH. INTERLEAD
FLASH SHALL NOT EXCEED 0.010" (0.254mm) PER SIDE
.0250
(0.635)
BSC
GN16 (SSOP) 0502
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ThinSOT is a trademark of Linear Technology Corporation.
1956f
28
Linear Technology Corporation
LT/TP 0303 2K • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
 LINEAR TECHNOLOGY CORPORATION 2001