Impala ILC6380 Sot-89 step-up dual-mode switcher with shutdown Datasheet

Impala Linear Corporation
ILC6380/81
SOT-89 Step-up Dual-Mode Switcher with Shutdown
Package Features
General Description
100mA boost converter in 5-lead SOT-89 package using
both PFM and PWM conversion techniques. In normal
operation the ILC6380 runs in PWM mode running at one of
three fixed frequencies. At light loads the ILC6380 senses
when the duty cycle drops to approximately 10%, and automatically switches into a power-saving PFM switching technique. This maintains high efficiencies both at full load and
in system sleep conditions.
Only 3 external components are needed to complete the
switcher design, and standard voltage options of 2.5, 3.3,
and 5.0V at ±2.5% accuracy feature on-chip phase compensation and soft-start design.
ILC6381 drives an external transistor for higher current switcher design, with all of the features and benefits of the ILC6380.
!
!
!
!
85% efficiency at 50mA
Start-up voltages as low as 900mV
±2.5% accurate outputs
Complete switcher design with only 3 external
components
! 50, 100 and 180kHz switching frequency versions
available
! Shutdown to 0.5µA Iq
! External transistor option allows several hundred
milliamp switcher design
Applications
! Cellular Phones, Pagers
! Portable Cameras and Video Recorders
! Palmtops and PDAs
Block Diagram
Ordering Information
LX
VL X LIMI TER
V DD
Slow Start
V OUT
BUFFER
Vr e f
V SS
PWM/ PFM Controll ed
OSC
Phase com p
50/ 100/180KHz
EXT
-
CE
CHI P ENABLE
+
V DD is i nternall y connected to the VO
UT
pi n.
Pin Package Configurations
LX
V SS
5
4
SOT -89-5
VS S
2
N/C VO UT
(TOP VI EW)
3
CE
Impala Linear Corporation
ILC6380/1 1.4
4
SOT -89-5
(TOP VI EW)
1
EXT
5
1
2
N/C
VO UT
3
CE
ILC6380CP-25
ILC6380CP-33
ILC6380CP-50
ILC6380CP-25
ILC6380CP-33
ILC6380CP-50
ILC6380CP-25
ILC6380CP-33
ILC6380CP-50
ILC6381CP-25
ILC6381CP-33
ILC6381CP-50
ILC6381BP-25
ILC6381BP-33
ILC6381BP-50
ILC6381AP-25
ILC6381AP-33
ILC6381AP-50
2.5V ± 2.5%@50kHz
3.3V ± 2.5%@50kHz
5.0V ± 2.5%@50khz
2.5V ± 2.5%@100kHz
3.3V ± 2.5%@100kHz
5.0V ± 2.5%@100kHz
2.5V ± 2.5%@180kHz
3.3V ± 2.5%@180kHz
5.0V ± 2.5%@180kHz
2.5V ± 2.5%@50kHz, external xtor
3.3V ± 2.5%@50kHz, external xtor
5.0V ± 2.5%@50kHz, external xtor
2.5V ± 2.5%@100kHz, external xtor
3.3V ± 2.5%@100kHz, external xtor
5.0V ± 2.5%@100kHz, external xtor
2.5V ± 2.5%@180kHz, external xtor
3.3V ± 2.5%@180kHz, external xtor
5.0V ± 2.5%@180kHz, external xtor
*Standard product offering comes in tape & reel, quantity
1000 per reel, orientation right for SOT-89
(408) 574-3939
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Sept 1999
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SOT-89 Step-up Dual-Mode Switcher with Shutdown
Absolute Maximum Ratings (TA = 25°C)
Parameter
VOUT Input Voltage
Voltage on pin LX
Current on pin LX
Voltage on pin EXT
Current on pin EXT
CE Input Voltage
Continuous Total Power Dissipation
Operating Ambient Temperature
Storage Temperature
Symbol
VOUT
VLX
ILX
VEXT
IEXT
VCE
PD
TOPR
TSTG
Ratings
12
12
400
VSS-0.3~VOUT+0.3
±50
12
500
-30~+80
-40~+125
Units
V
V
mA
V
mA
V
mW
°C
°C
Stresses above those listed under ABSOLUTE MAXIMUM RATINGS may cause permanent device failure. Functionality at
or above these limits is not implied. Exposure to absolute maximum ratings for extended periods may affect device reliability. Operating ranges define those limits between which the functionality of the device is guaranteed.
Electrical Characteristics
VOUT = 5.0V, FOSC = 100kHz TA - 25°C. Unless otherwise specified, VIN = VOUT x 0.6, IOUT = 50mA. See schematic, figure 3
Parameter
Output Voltage
Input Voltage
Oscillation Startup
Voltage
Operation Startup
Voltage
No-Load Input Current
Supply Current 1
Symbol
VOUT
VIN
VST
Min
4.875
Typ
5.000
LX = 10kΩ pull-up to 5V, VOUT = VST
Max
5.125
10
0.8
Units
V
V
V
0.9
V
VST1
IOUT = 1mA
IIN
IDD 1
IOUT = 0mA (See Note 1)
LX = 10kΩ pull-up to 5V, VOUT = 4.5V
23.0
78.6
46.0
131.1
µA
µA
IDD 2
RSWON
LX = 10kΩ pull-up to 5V, VOUT = 5.5V
LX = 10kΩ pull-up to 5V, VOUT = 4.5V
6.9
1.3
13.8
2.3
µA
Ω
85
100
1.0
115
µA
kHz
80
87
92
%
5
10
20
0.5
%
µA
V
0.20
V
0.25
-0.25
µA
µA
1.1
V
(See Note 2)
Supply Current 2
LX Switch-On
Resistance
LX Leakage Current
Oscillator Freq.
Conditions
ILXL
FOSC
Maximum Duty Ration
MAXDTY
PFM Duty Ration
Stand-by Current
CE “High” Voltage
PFMDTY
ISTB
VCEH
CE “Low” Voltage
VCEL
CE “High” Current
CE “Low” Current
ICEH
ICEL
LX Limit Voltage
VLXLMT
Efficiency
Slow Start Time
EFFI
TSS
No external components, VOUT = VLX = 10V
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
Measuring of LX waveform
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
Measuring of LX on-time
VIN = 4.75V, Measuring of LX on-time
LX = 10kΩ pull-up to 5V, VOUT =4.5V
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
Existence of LX Oscillation
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
Stopped LX Oscillation
LX = 10kΩ pull-up to 5V, VOUT = VCE = 4.5V
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
VCE = 0V
LX = 10kΩ pull-up to 5V, VOUT = 4.5V,
FOSC > FOSC x 2 (See Note 2)
0.75
0.7
85
10
%
msec
Notes:
1. The Schottky diode (S.D.), in figure 3 must be type MA735, with Reverse current (IR) < 1.0µA at reverse voltage (VR)=10.0V
2. “Supply Current 1” is the supply current while the oscillator is continuously oscillating. In actual operation the oscillator
periodically operates which results in less average power consumption.
The current that is actually provided by external VIN source is represented by “No-Load Input Current(IIN)”
3. Switching frequency is determined by delay time of internal comparator to turn Lx “off”, and minimum “on” time as determined
by MAXDTY spec.
Impala Linear Corporation
ILC6380/1 1.4
(408) 574-3939
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Sept 1999
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SOT-89 Step-up Dual-Mode Switcher with Shutdown
Electrical Characteristics ILC6380BP-50
VOUT = 5.0V, FOSC = 100kHz TA = 25°C. Unless otherwise specified, VIN = VOUTX0.6, IOUT = 50mA. See the schematic, figure 4.
Parameter
Output Voltage
Input Voltage
Oscillation Startup Voltage
Operation Startup Voltage
Supply Current 1
Symbol
VOUT
VIN
VST2
VST1
IDD 1
Conditions
Test Circuit of Figure 2
VOUT = VST2
IOUT = 1mA
EXT = 10kΩ pull-up to 5V,
VOUT = 4.5V
EXT = 10kΩ pull-up to 5V,
VOUT = 5.5V
EXT = 10kΩ pull-up to 5V,
VOUT = 4.5V, VEXT = VOUT – 0.4V
EXT = 10Ω pull-up to 5V,
VOUT = 4.5V, VEXT = VOUT - 0.4V
EXT = 10kΩ pull-up to 5V, VOUT =
4.5V, Measuring of EXT waveform
EXT = 10kΩ pull-up to 5V, VOUT =
4.5V, Measuring of EXT high state
EXT = 10kΩ pull-up to 5V, VOUT =
4.5V, Existence of Oscillation
EXT = 10kΩ pull-up to 5V, VOUT =
4.5V, Stopped EXT Oscillation
EXT: 10kΩ pull-up to 5V,
VOUT = 4.5V, VCE = VOUT X 0.95V
EXT = 10kΩ pull-up to 5V,
VOUT = 4.5V, VCE = 0V
(See Note 2)
Supply Current 2
IDD 2
EXT “High” On-Resistance
REXTH
EXT “Low” On-Resistance
REXTL
Oscillator Frequency
FOSC
Maximum Duty Ratio
MAXDTY
CE “High” Voltage
VCEH
CE “Low” Voltage
VCEL
CE “High” Current
ICEH
CE “Low” Current
ICEL
Efficiency
Slow Start Time
Min
4.875
Typ
5.000
78.6
Max
5.125
10
0.8
0.9
131.1
Units
V
V
V
V
µA
6.9
13.8
µA
30
50
Ω
30
50
Ω
85
100
115
kHz
80
87
92
%
0.75
V
EFFI
TSS
0.20
V
0.25
µA
-0.25
µA
85
10
%
msec
Notes:
1. The Schottky diode (S.D.), in figure 3 must be type MA735, with Reverse current (IR) < 1.0µA at reverse voltage (VR)=10.0V
2. “Supply Current 1” is the supply current while the oscillator is continuously oscillating. In actual operation the oscillator periodically
operates which results in less average power consumption.
The current that is actually provided by external VIN source is represented by “No-Load Input Current (IIN)”
Typical Applications
VOUT
VOUT
3
2
3
1
+
ILC6380
2
1
L
L
VIN
CE
SD
CE
SD
+
CL
ILC6381
VIN
CL
CB
4
4
5
5
Tr
RB
GND
Figure 4
Figure 3
L: 100µH ( SUMIDA, CD-54)
SD: Diode (Schottky diode; MATSUSHITA MA735)
CL: 16V 47µF (Tantalum Capacitor; NICHICON, F93)
Impala Linear Corporation
ILC6380/1 1.4
(408) 574-3939
L:
SD:
CL:
RB:
CB:
Tr:
47µH ( SUMIDA, CD-54)
Diode (Schottky diode; MATSUSHITA MA735)
16V 47µF (Tantalum Capacitor; NICHICON, F93)
1kW
3300pF
2SC3279, 2SDI628G
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SOT-89 Step-up Dual-Mode Switcher with Shutdown
Functions and Operation
The ILC6380 performs boost DC-DC conversion by controlling the
switch element shown in the circuit below
When the switch is closed, current is built up through the inductor.
When the switch opens, this current has to go somewhere and is
forced through the diode to the output. As this on and off switching continues, the output capacitor voltage builds up due to the
charge it is storing from the inductor current. In this way, the output voltage gets boosted relative to the input. The ILC6380 monitors the voltage on the output capacitor to determine how much
and how often to drive the switch.
In general, the switching characteristic is determined by the output
voltage desired and the current required by the load. Specifically
the energy transfer is determined by the power stored in the coil
during each switching cycle.
PL = ƒ(tON, VIN)
The ILC6380 and ILC6381 use a PWM or Pulse Width Modulation
technique. The parts come in one of three fixed internal frequencies: 50, 100, or 180kHz. The switches are constantly driven at
these frequencies. The control circuitry varies the power being
delivered to the load by varying the on-time, or duty cycle, of the
switch. Since more on-time translates to higher current build-up in
the inductor, the maximum duty cycle of the switch determines the
maximum load current that the device can support. The ILC6380
and ILC6381 both support up to 87% duty cycles, for maximum
usable range of load currents.
There are two key advantages of the PWM type controllers. First,
because the controller automatically varies the duty cycle of the
switch’s on-time in response to changing load conditions, the
PWM controller will always have an optimized waveform for a
steady-state load. This translates to very good efficiency at high
currents and minimal ripple on the output. [Ripple is due to the output cap constantly accepting and storing the charge received from
the inductor, and delivering charge as required by the load. The
“pumping” action of the switch produces a sawtooth-shaped voltage as seen by the output.]
The other key advantage of the PWM type controllers is that the
radiated noise due to the switching transients will always occur at
the (fixed) switching frequency. Many applications do not care
much about switching noise, but certain types of applications,
especially communication equipment, need to minimize the high
frequency interference within their system as much as is possible.
Using a boost converter requires a certain amount of higher frequency noise to be generated; using a PWM converter makes that
noise highly predictable; thus easier to filter out.
Impala Linear Corporation
ILC6380/1 1.4
(408) 574-3939
Dual Mode Operation
But there are downsides of PWM approaches, especially at very
low currents. Because the PWM technique relies on constant
switching and varying duty cycle to match the load conditions,
there is some point where the load current gets too small to be
handled efficiently. An actual switch consumes some finite amount
of current to switch on and off; at very low currents this can be of
the same magnitude as the load current itself, driving switching
efficiencies down to 50% and below. The ILC6380 and ILC6381
overcome this limitation by automatically switching over to a PFM,
or Pulse Frequency Modulation, technique at low currents. This
technique conserves power loss by only switching the output if the
current drain requires it. As shown in the diagram below, the waveform actually skips pulses depending on the power needed by the
output. [This technique is also called “pulse skipping” because of
this characteristic.]
Switch Waveform
VSET
VOUT
In the ILC6380 and ILC6381, this switchover is internally set to be
at the point where the PWM waveform hits approximately 10%
duty cycle. So the PFM mode is running at 10% duty cycle at the
rated frequency; for 100kHz part this means a constant on-time of
1msec. This not only is ideal for efficiency at these low currents,
but a 10% duty cycle will have much better output ripple characteristics than a similarly configured PFM part, such as the ILC6390
and ILC6391.
The Dual-Mode architecture was designed specifically for those
applications, like communications, which need the spectral predictability of a PWM-type DC-DC converter, yet which also needs
the highest efficiencies possible, especially in Shutdown or
Standby mode. [For other conversion techniques, please see the
ILC6370/71 and ILC6390/91 datasheets.]
Other Considerations
The other limitation of PWM techniques is that, while the fundamental switching frequency is easier to filter out since it’s constant,
the higher order harmonics of PWM will be present and may have
to be filtered out, as well. Any filtering requirements, though, will
vary by application and by actual system design and layout, so
generalizations in this area are difficult, at best.
However, PWM control for boost DC-DC conversion is widely
used, especially in audio-noise sensitive applications or applications requiring strict filtering of the high frequency components.
Impala’s products give very good efficiencies of 85% at 50mA output (5V product), 87% maximum duty cycles for high load conditions, while maintaining very low shutdown current levels of
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SOT-89 Step-up Dual-Mode Switcher with Shutdown
0.5mA. The only difference between the ILC6380 and ILC6381
parts is that the 6381 is configured to drive an external transistor
as the switch element. Since larger transistors can be selected for
this element, higher effective loads can be regulated.
Start-up Mode
The ILC6380 has an internal soft-start mode which suppresses
ringing or overshoot on the output during start-up. The following
diagram illustrates this start-up condition’s typical performance:
VOUT MIN
VIN - Vf
T SOFT-START
The capacitor should, in general, always be tantalum type, as tantalum has much better ESR and temperature stability than other
capacitor types. NEVER use electrolytics or chemical caps, as the
C-value changes below 0×C so much as to make the overall
design unstable.
Different C-values will directly impact the ripple seen on the output
at a given load current, due to the direct charge-to-voltage relationship of this element. Different C-values will also indirectly affect
system reliability, as the lifetime of the capacitor can be degraded
by constant high current influx and outflux. Running a capacitor
near its maximum rated voltage can deteriorate lifetime as well;
this is especially true for tantalum caps which are particularly sensitive to overvoltage conditions.
(~10msec)
In general, then, this capacitor should always be 47mF, Tantalum,
16V rating.
t=0
External Components and Layout Consideration
The ILC6380 is designed to provide a complete DC-DC convertor
solution with a minimum of external components. Ideally, only
three externals are required: the inductor, a pass diode, and an
output capacitor.
The inductor needs to be of low DC Resistance type, typically 1Ω
value. Toroidal wound inductors have better field containment (less
high frequency noise radiated out) but tend to be more expensive.
Some manufacturers like Coilcraft have new bobbin-wound inductors with shielding included, which may be an ideal fit for these
applications. Contact the manufacturer for more information.
The inductor size needs to be in the range of 47mH to 1mH. In
general, larger inductor sizes deliver less current, so the load current will determine the inductor size used.
For load currents higher than 10mA, use an inductor from 47mH
to 100mH. [The 100mH inductor shown in the datasheet is the
most typical used for this application.]
For load currents of around 5mA, such as pagers, use an inductor
in the range of 100mH to 330mH. 220mH is the most typical value
used here.
For lighter loads, an inductor of up to 1mH can be used. The use
of a larger inductor will increase overall conversion efficiency, due
to the reduction in switching currents through the device.
For the ILC6381, using an external transistor, the use of a 47mH
inductor is recommended based on our experience with the part.
Note that these values are recommended for both 50kHz and
100kHz operation. If using the ILC6380 or ILC6381 at 180kHz,
the inductor size can be reduced to approximately half of these
stated values.
Impala Linear Corporation
ILC6380/1 1.4
(408) 574-3939
The diode must be of shottkey type for fast recovery and minimal
loss. A diode rated at greater than 200mA and maximum voltage
greater than 30V is recommended for the fastest switching time
and best reliability over time. Different diodes may introduce different levels of high frequency switching noise into the output
waveform, so trying out several sources may make the most
sense for your system.
For the IL6381, much of the component selection is as described
above, with the addition of the external NPN transistor and the
base drive network. The transistor needs to be of NPN type, and
should be rated for currents of 2A or more. [This translates to
lower effective on resistance and, therefore, higher overall efficiencies.] The base components should remain at 1kΩ and
3300pF; any changes need to be verified prior to implementation.
As for actual physical component layout, in general, the more
compact the layout is, the better the overall performance will be. It
is important to remember that everything in the circuit depends on
a common and solid ground reference. Ground bounce can directly affect the output regulation and presents difficult behavior to
predict. Keeping all ground traces wide will eliminate ground
bounce problems.
It is also critical that the ground pin of CL and the VSS pin of the
device be the same point on the board, as this capacitor serves
two functions: that of the output load capacitor, and that of the
input supply bypass capacitor.
Layouts for DC-DC converter designs are critical for overall performance, but following these simple guidelines can simplify the
task by avoiding some of the more common mistakes made in
these cases. Once actual performance is completed, though, be
sure to double-check the design on actual manufacturing prototype product to verify that nothing has changed which can affect
the performance.
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SOT-89 Step-up Dual-Mode Switcher with Shutdown
Typical Performance Characteristics General conditions for all curves
OUTPUT VOLTAGE vs. OUTPUT CURRENT
EFFICIENCY vs. OUTPUT CURRENT
ILC6380CP-30
3.2
100
ILC6380CP-30
3.1
80
EFFICIENCY: EFFI (%)
OUTPUT VOLTAGE VOUT (V)
L = 1000µH
C = 47µF (Tantalum)
3.0
2.9
VIN = 2.0V
2.8
VIN = 1.5V
VIN = 1.0V
2.7
2.6
VIN = 2.0V
60
VIN = 1.5V
VIN = 1.0V
40
20
L = 1000µH
C = 47µF (Tantalum)
0
0
40
80
120
160
0
200
0
40
80
120
160
OUTPUT CURRENT IOUT (mA)
OUTPUT CURRENT IOUT (mA)
INPUT CURRENT vs. INPUT VOLTAGE
RIPPLE VOLTAGE vs. OUTPUT CURRENT
ILC6380CP-30
ILC6380CP-30
50
100
L = 100µH
L = 1000µH
C = 47µF (Tantalum)
80
C = 47µF (Tantalum)
IOUT = 0 (no load)
RIPPLE Vr (mVp-p)
INPUT CURRENT (µA)
RL = 0
40
30
20
10
VIN = 2.0V
60
VIN = 1.5V
40
VIN = 1.0V
20
0
0
1.0
1.2
1.4
1.6
1.8
2.0
0
40
INPUT VOLTAGE VIN (V)
Impala Linear Corporation
ILC6380/1 1.4
80
120
160
OUTPUT CURRENT IOUT (mA)
(408) 574-3939
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