SEMTECH SC339SKTRT

SC339
Ultra Low Output Voltage
Linear FET Controller
POWER MANAGEMENT
Features
Description
The SC339 is an ultra-low output voltage, linear power
supply controller designed to simplify power management for notebook PCs. It is part of Semtech’s Smart
LDO TM family of products. The SC339 has a user
adjustable output that can be set anywhere between 0.5V
and 3.3V using two external resistors.
± 1% Voltage Accuracy Over-Temperature
Low Shutdown Current
Runs Off 5V Supply
Ultra-Fast Transient Response
Enable Control for the Output
Power Good Monitoring and Signaling for the Output
Gate Drive from Input Supply Enables Use of
N-Channel MOSFET
User Selectable Dropout Voltage
Under-Voltage Protection for the Output
SOT-23 6-pin Surface Mount Package
Compatible with Ceramic Capacitors
Low Ripple Output
Internal 1ms soft-start requires no external components
Fully WEEE and RoHS compliant
SC339 features include tight output voltage regulation (±
1% over 0°C to +85°C), enable control, open drain power
good signal, under-voltage protection and soft-start. The
enable pin allows the part to enter a very low power standby
mode. Pulling it high enables the output. The power good
pin is an open drain and asserts low when the voltage at
the adjust pin is below 88% (typ) of nominal. If the voltage
at the adjust pin is below 50% (typ) of nominal, the undervoltage protection circuitry will shut down the output. The
SC339 is available in a tiny SOT-23 6-pin surface mount
package.
Applications
Notebook PCs
Desktop Computers
Battery Powered Devices
Portable Instruments
Typical Application Circuit
1.2V +/-5% IN
IRF7311
or similar
C1
Vout = (1+R1/R2)*0.5
1.05V @ 3A
C2
5V IN
R1
IN
DRV
GND SC339 ADJ
1.05V
Enable
EN
1.05V
Power Good
PGD
R3 (1)
C4
R2
Notes:
(1) Optional Components to use with ceramic output
capacitors (C2)
Sept 11, 2006
1
C3 (1)
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SC339
PRELIMINARY
POWER MANAGEMENT
Absolute Maximum Ratings
Exceeding the specifications below may result in permanent damage to the device or device malfunction. Operation outside of the parameters specified in the
Electrical Characteristics section is not implied. Exposure to absolute maximum rated conditions for extended periods of time may affect device reliability.
Parameter
Symbol
Maximum
Units
VIN
-0.3 to +6
V
VDRV
-0.3 to VIN + 0.3V
V
VADJ, VPGD
-0.3 to VIN + 0.3V
V
Enable Pin
VEN
-0.3 to VIN + 0.3V
V
Thermal Impedance Junction to Ambient
θJA
190
°C/W
Thermal Impedance Junction to Case
θJC
81
°C/W
Operating Ambient Temperature Range
TA
-40 to +85
°C
Operating Junction Temperature Range
TJ
-40 to +125
°C
Storage Temperature Range
TSTG
-65 to +150
°C
Lead Temperature (Soldering) 10 Sec.
TLEAD
300
°C
ESD Rating (Human Body Model)
VESD
2
kV
Input Supply Voltage
Drive Pin
Adjust and Power Good Pin
Electrical Characteristics
Unless specified: TA = 25°C, VIN = VEN = 5V ± 5%, VPWR(1) = 1.5V ± 5%, 0A ≤ IOUT ≤ 3A. Values in bold apply over full operating ambient temperature range.
Parameter
Symbol
Conditions
Min
Typ
Max
Units
4.5
5
5.5
V
Supply Voltage
VIN
Quiescent Current
IQ
VIN = 5V
130
200
μA
IQ(OFF)
EN low
0.1
1.0
μA
Start Threshold
VUVLO
VIN rising
4.20
V
Hysteresis
VHYST
VIN falling
0.10
V
VIH
Output on
VIL
Output off
Standby Current
Input Under-Voltage Lockout
EN
Enable Input Threshold
Enable Input Bias Current
© 2006 Semtech Corp.
2.8
V
VIN = VEN = 5V
2
1.8
-1
+1
μA
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SC339
POWER MANAGEMENT
Electrical Characteristics
Parameter
Symbol
Conditions
Min
Typ
Max
Units
Adjust Input Bias Current
IADJ
VADJ = 0.5V
-100
0
+100
nA
Reference Voltage
VADJ
0°C ≤ TA ≤ +85°C
-1%
0.500
1%
V
Sourcing
5
20
mA
Sinking
5
20
mA
VDRV
Full On, IDRV = 0mA, VIN = 5V
4.70
4.85
V
VTH(UV)
Measured at ADJ pin
40
50
60
%VADJ
Power Good Threshold(3)
VTH(PGD)
Measured at ADJ pin
-15
-12
-8
%VADJ
Output Logic Low Voltage
VPGD
VADJ = 0.4V, IPGD = -1mA
0.4
V
Power Good
Leakage Current
IPGD
VADJ = 0.5V, 0V ≤ VPGD ≤ VIN
-1
0
+1
μA
tr
From EN rising to
99% of VOUT
500
1000
2000
μs
ADJ
DRV
Output Current
IDRV
Output Voltage
Output Under-Voltage Protection
Trip Threshold(2)
PGD
Soft-Start
Output Rise Time 10% VOUT
to 90% VOUT, VOUT = 1.05V
Notes:
1) VPWR = input voltage to pass device drain (or source depending upon orientation of FET).
2) If V TH(UV) is exceeded for longer than 1ms (nom.) the protection circuitry will shut down the output.
3) During start-up only, V TH(PGD) is -6% (typical), then switches to -12% (typical).
© 2006 Semtech Corp.
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SC339
PRELIMINARY
POWER MANAGEMENT
Pin Configuration
Ordering Information
Top View
Part Number
IN
1
6
DRV
SC339SKTRT
GND
2
5
ADJ
SC339EVB
EN
3
4
PGD
Package
SOT-23 6 Pin
Evaluation Board
Notes:
1) Only available in tape and reel packaging. A reel contains 2500
devices.
2) VIN = 5V
3) VADJ is ± 1% over 0°C ≤ TA ≤ +85°C.
4) Lead-free product. This product is fully WEEE and RoHS
compliant.
(SOT-23 6L)
Marking Information
Marking for SOT23, 6 lead package:
yyww = Datecode (Example: E652)
Pin Descriptions
Pin
Pin Name
1
IN
2
GND
3
EN
4
PGD
Power good signal output for VOUT
5
ADJ
Regulator sense input - used for sensing the output voltage for power good and
under-voltage and to set the output voltage
6
DRV
© 2006 Semtech Corp.
Pin Function
5V supply
Ground
Active high enable control - connect to IN if not being used - do not allow to float
Output of regulator - drives the gate of an N-channel MOSFET to maintain VOUT
set by R1 and R2
4
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SC339
POWER MANAGEMENT
Block Diagram
IN
EN
0.5V
Bandgap
Reference
Shutdown
Control
Vref
( 0.5V)
DRV
+
-
+
Under
Voltage
Control
Vref
Error
Amplifier
ADJ
0.5 VBG
Undervoltage
Comparator
PGD
+
0.88 VBG
(0.95 VBG
At start-up)
Power Good
Comparator
© 2006 Semtech Corp.
5
GND
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SC339
PRELIMINARY
POWER MANAGEMENT
Applications Information
Theory Of Operation
stabilize. The power-up is very smooth and monotonic.
The SC339 linear FET controller provides a simple
way to drive an N-channel MOSFET to produce tightly
regulated output voltages from an available,
higher, supply voltage. It takes its power from
the 5V system supply, drawing 130μA (typ) while
operating.
OCP and Power Supply Sequencing
It contains an internal bandgap reference which is
compared to the output voltage via a resistor divider.
The resistor divider is external and user selectable. The
drive pin (DRV) can pull up to a guaranteed minimum of
4.7V. Thus, the device can be used to regulate a large
range of output voltages by careful selection of the
external MOSFETs (see Component Selection on this
page).
The SC339 includes an active high enable control (EN). If
this pin is pulled low, the drive pin is pulled low, turning
off the N-channel MOSFET. If the pin is pulled up to 2.8V
≤ VEN ≤ VIN, the drive pin is enabled. This pin should not
be allowed to float.
The SC339 has a power good output (PGD) which is an
open drain output that pulls low if the related output is
below the power good threshold (-12% of the programmed
output voltage typical). The power good circuitry is active
if the device is enabled, regardless of the state of the
over-current latch.
An over-current protection circuit monitors the output voltage.
If the output voltage drops below 50% (typical) of nominal,
as would occur during an over-current or short condition, the
device will pull the drive pin low and latch off. Toggle the
power supply or enable pin to reset the latch condition.
Drive Output
The drive output is source and sink capable. The drivers
both source and sink 20mA of current typically at 5V IN.
Soft-Start and Power Good Timing
At start-up, the internal reference is switched from its
normal 0.5VDC to a 1ms (typical) linear ramp. The output
voltage tracks the ramp until 0.5V is reached. The PWRGD
signal is held low until the output has been in regulation
approximately 500μsec to allow the output voltage to
© 2006 Semtech Corp.
The SC339 has output under-voltage protection that
looks at the output to see if it is: a) less than 50% (typical) of its nominal value and, b) VDRV for that output is
within 350mV (typical) of maximum. If both of these
criteria are met, there is a 1ms (typical) delay and
then the output is shut down. This provides inherent
immunity to UV shutdown at start-up (which may occur while
the output capacitors are being charged).
At star t-up, it is necessar y to ensure the power
supplies and enable are sequenced correctly to
avoid erroneous latch-off. For UV latch-off not to occur at start-up due to sequencing issues, the voltage supplied to the MOSFET drain should be greater
than the output under-voltage threshold when that
output is enabled. This assumes that the drop through the
pass MOSFET is negligible. If not, then this drop needs to
be taken into account also since:
VOUT = VDRAIN - (IOUT x RDS(ON))
If the supply to the SC339 IN pin comes up before the
supply to the MOSFET drain, then that output should be
enabled after the supply to the MOSFET drain is applied
- the power good signal for this rail would be ideal. If the
power supply to the MOSFET drain comes up before the
power supply to the SC339 IN pin, then the output can either
be enabled with the supply to the IN pin or afterwards.
Please note the following example:
SC339 powered from 5V, the MOSFET (VDRAIN) powered from
1.8V, set for 1.5VOUT. Worst-case: under-voltage threshold is
60% (over temperature) of 1.5V, or 0.9V. The typical enable
threshold is ~2.4V, see Figure 1 on Page 7.
Component Selection
Output Capacitors: low ESR capacitors such as Sanyo
POSCAPs or Panasonic SP-caps are recommended for
bulk capacitance, with ceramic bypass capacitors for
decoupling high frequency transients. Ceramic output
capacitors may be used; however, use of ceramic output
capacitors requires compensation on the DRV output.
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SC339
POWER MANAGEMENT
Applications Information (Cont.)
Input Capacitors: placement of low ESR capacitors such
as Sanyo POSCAPs or Panasonic SP-caps at the input to
the MOSFET (VDRAIN) will help to hold up the power supply
during fast load changes, thus improving overall transient
response. If VDRAIN is located at the bulk capacitors for
the upstream voltage regulator, additional capacitance
may not be required. In this case a 0.1μF ceramic
capacitor will suffice. The 5V bias supply to the SC339
should be bypassed with a 0.1μF ceramic capacitor.
Note: RDS(ON) must be met at all temperatures and at the minimum VGS condition.
Setting The Output Voltage: the adjust pin connects
directly to the inverting input of the error amplifier, and
the output voltage is set using external resistors (please
refer to the Typical Application Circuit on Page 1).
Using output 1 as an example, the output voltage can be
calculated as follows:
MOSFETs: ver y low or low threshold N-channel
MOSFETs are required. Select FETs rated for V GS
of 2.7V or lower. For the device to work under all
operating conditions, a maximum RDS(ON) must be met to
ensure that the output will never go into dropout:
R1
VOUT = 0.5 • ( 1 + —— )
R2
The input bias current for the adjust pin is so low that
it can be safely ignored. To avoid picking up noise, it is
recommended that the total resistance of the feedback
chain be less than 100kΩ. With ceramic capacitors, a
recommended divider current of >100μA is recommended
to keep the FET conducting during light load conditions to
improve transient response.
VIN(MIN) ― VOUT(MAX)
RDSON(MAX) = ——————— Ω
IOUT(MAX)
2.8V
SC339 Supply Comes Up Before MOSFET Drain Supply
2.7V
MOSFET Drain Supply Comes Up Before SC339 Supply
Power Supply Sequencing
© 2006 Semtech Corp.
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SC339
PRELIMINARY
POWER MANAGEMENT
Applications Information (Cont.)
Table 1 lists recommended resistor values for some standard output voltages. All resistors are 1%, 1/10W.
Total DC error = ±2.25% = 23.6mV
This leaves ±2.75% = 28.875mV for the load transient ESR
spike, therefore:
The maximum output voltage that can be obtained
from each output is determined by the input supply
voltage and the RDS(ON) and gate threshold voltage of the
external MOSFET. Assuming that the MOSFET gate
threshold voltage is sufficiently low for the output
voltage chosen and the worst-case drive voltage, VOUT(MAX)
is given by:
28.875mV
RESR(MAX) = —————— = 11.55mΩ
2.5A
Bulk capacitance required is given by:
VOUT (MAX) = VDRAIN(MIN) ― IOUT(MAX) • RDSON(MAX)
VOUT (V)
R1 or R3 (kΩ)
R2 or R4 (kΩ)
1.05
11.0
10.0
1.2
14.0
10.0
1.5
20.0
10.0
2.5
45.3
11.3
3.3
63.4
11.3
dl • τ
CBULK(MIN) = ——— = μF
dV
Where dI is the maximum load current step, t is the
maximum regulator response time and dV is the
allowable voltage droop. Therefore with dI = 2.5A,
t = 1μs, and dV = 28.875mV:
6
2.5 • 1 • 10¯
CBULK(MIN) = ———————— = 87μF
3
28.875 • 10¯
Recommended Resistor Values For SC339
Design Example
So if we use 1% VOUT set resistors we would select
100μF, 12mΩ POSCAP for output capacitance (which
assumes that local ceramic bypass capacitors will
absorb the balance of the (12 - 11.55)mΩ ESR
requirement - otherwise 10mΩ capacitors should be
used).
If we use 0.1% set resistors, then the total DC error
becomes ±1.35% = ±15.75mV, leaving ±3.65% = 38.33mV
for the ESR spike. In this case:
Goal: 1.05V±5% @ up to 2.5A from 1.2V±5% and 5V±5%
Solution 1: No Passive Droop
Total window for DC error, ripple and transient is
±52.5mV.
Since this device is linear and assuming that it has been
designed to not ever enter dropout, there is negligible ripple
on the output.
38.33mV = 15.33mΩ
RESR(MAX) = ————
2.5A
The DC error for this output is the sum of:
and,
6
2.5 • 1 • 10¯
= 65μF
CBULK(MIN) = ———————
3
38.33 • 10¯
VADJ accuracy = ±1% = ±10.5mV
Feedback chain tolerance = ±1% = ±10.5mV
So for 0.1% resistors we could use 1 x 100μF, 15mΩ
POSCAP for output capacitance.
Load regulation = ±0.25% = ±2.6mV
Resistors per Table 1 should be 11.0kΩ (top) and 10.0kΩ
(bottom).
© 2006 Semtech Corp.
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SC339
POWER MANAGEMENT
Applications Information (Cont.)
This is a ver y severe example, since the output
voltage is so low, therefore the allowable window
is ver y small. See Solution 2 for an alternate
circuit. For higher output voltages the components
required will be less stringent.
Solution 2: Using Passive Droop
1.2V +/-5% IN
C1
0.1uF
RDROOP
1.075V
1.05V @ 2.5A
The input capacitance needs to be large enough to stop
the input supply from collapsing below -5% (i.e., the
design minimum) during output load steps. If the input
to the pass MOSFET is not local to the supply bulk
capacitance then additional bulk capacitance may be
required.
C3
R1
100uF, 25mOhm POSCAP
(VIN(MIN) ― VOUT )
(1.14 ― 1.05)
RDSON(MAX) = —————— = —————— = 36mΩ
IOUT(MAX)
2.5
MOSFET SELECTION
Si5406DC
NTHS5404
SOT-23 Footprint
IRLMS2002
FDN337N
(when Input
is > 1.2V
for 1.05V
output)
© 2006 Semtech Corp.
Vgs
0.6V
0.6V
Rds-on
20mΩ
25mΩ
Imax
9.5A
7.2A
Vgs
1V
0.7V
Rds-on
30mΩ
65mΩ
Imax
5.2A
2.2A
EN
3
5
ADJ
GND
2
6
DRV
IN
1
If 1% set resistors are used, the total DC error will be
±2.25% = 24mV. Thus, at no load, the minimum output
voltage will be given by:
SO-8 Footprint
FDS6682
IRF7456
1206 Footprint
SC339
PGD
Passive droop allows us to use almost the full output
tolerance window for transients, therefore making the
o u t p u t c a p a c i to r s e l e c t i o n s i m p l e r a n d l e s s
expensive. The trade-offs are the cost of the droop
resistor versus the reduction in output capacitor cost,
and the reduction in headroom which impacts MOSFET
selection. The top of the feedback chain connects to the
input side of RDROOP, and the output is set for 1.075V. Thus
at no load, VOUT will be 1.075V (or 1.05V + 2.4%) and at IOUT
= 2.5A, VOUT will be 1.025V (or 1.05V - 2.4%).
So a MOSFET rated for VGS = 2.7V will be required, with an
RDS(ON)(MAX) (over-temperature) given by:
Imax
14A
16A
U1
4
10.0k
VGS = (4.4 ― 1.1025) = 3.3V
Rds-on
9mΩ
6.5mΩ
11.0k
R2
MOSFET selection: since the input voltage to the SC339
is 5V±5%, the minimum available gate drive is:
Vgs
1.7V
1.5V
Q1
20mOhm
VOUT(MIN_NO_LOAD) = 1.075 ― 0.024 = 1.051V
This leaves 53.5mV for transient response, giving:
53.5mV
RESR(MAX) = ———— = 21.4mΩ and,
2.5A
6
2.5 • 1 • 10¯
CBULK(MIN) = ——————— = 47μF
53.5 •10¯3
Instead of 2 x 100μF, 12mΩ capacitors, we can use 1 x
47μF, 15mΩ capacitor.
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SC339
PRELIMINARY
POWER MANAGEMENT
Applications Information (Cont.)
Using Ceramic Capacitors
From this response we see that the system is not stable
as it has a phase margin of approximately 0 degrees.
SC339 is capable of operation using an all-ceramic solution, needing only an external R-C compensation. The
Typical Application schematic (R3, C3) from page 1 is reproduced here:
For stable operation we introduce a low frequency pole
and a zero. The low frequency pole is used to roll off the
gain quicker and the zero is used to increase the bandwidth of the system.
1.2 V +/-5 % IN
IRF7311
or similar
C1
The Pole-Zero location:
V out = (1+R1/R2)*0.5
1.05 V @ 3A
C2
PHASE (deg)
Gain (dB)
5 V IN
R1
270
60
DRV
IN
Pin + Pcomp
GND
1.05V
Enable
SC339 ADJ
EN
PGD
1.05 V
Power Good
C4
Prout
Zin + Zcomp
Typical Applications Circuit
Gain (dB)
100
-20
Typical Frequency Response without Compensation and
Ceramic Output Capacitors:
Pcout
1K
10K
100K
1MEG
PHASE
FREQ (Hz)
10MEG
-90
-40
-180
-60
-270
PHASE (deg)
Low frequency pole
generated internally
Pin
SC339 Frequency Response with
Ceramic Output Capacitors and R-C Compensation
270
Low frequency zero
generated internally
Rout / Cout pole, moves with
the load current
Prout
Zin
40
180
20
Pcout
100
1K
10K
100K
High frequency pole
generated by ESR
and Output Capacitor
1MEG
From the above figure we can see that the overall response of the system is stable with a decent phase
margin
90
FREQ (Hz)
10MEG
It is important to select the external compensation zero
to be between 1 kHz and 5 kHz for optimum bandwidth
and phase margin. In this example we have selected
zero at approximately 3 kHz.
PHASE
-90
-20
-40
90
20
C 3 (1)
0,0
0,0
180
R2
Notes :
(1 ) Optional Components to use with ceramic output
capacitors (C2)
60
Ceramic Capacitor
Operation with
Compensation on DRV pin
40
R 3 (1)
Ceramic Capacitor operation
with very low ESR for the
output capacitor . We get a
three pole 1 zero system as
shown above and is unstable
without external compensation
-60
-180
The compensation values are calculated by the following
empirical equation:
-270
½•
SC339 Frequency Response with
Ceramic Output Capacitors and no Compensation
• R3 • C3 = 3kHz
We chose a low R3 compensation value to roll off gain.
R3 = 100 Ω.
© 2006 Semtech Corp.
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SC339
POWER MANAGEMENT
Applications Information (Cont.)
Now,
Layout Guidelines
C3 = ½ •
• R3 • 3kHz = 530nF
The advantages of using the SC339 to drive external
MOSFETs are:
We choose C3 = 470nF as the standard value.
Soft-Start Behavior
a) that the bandgap reference and control circuitry are in a
die that does not contain high power dissipating devices
At start-up, VOUT first ramps linearly from ground at the rate of
~0.5V/ms (+/- 25%) for about 800us. The linear ramping is
followed by a phase of smooth settling for about 700us at the
end of which the output has fully settled (to better than 1%).
and,
b) that the device itself does not need to be located right
next to the power devices. Thus very accurate output
voltages can be obtained since changes due to heating
effects will be minimal.
The total start-up time of about 1.5ms is kept within 1ms
- 2ms window, and this is regardless of the loading and
of the external components connected to the device.
The 0.1μF bypass capacitor should be located close to the
supply (IN) and GND pins, and connected directly to the
ground plane.
The feedback resistors should be located at the device,
with the sense line from the output routed from the load
(or top end of the droop resistor if passive droop is being
used) directly to the feedback chain. If passive droop is
being used, the droop resistor should be located next to the
load to avoid adding additional unplanned droop. Sense
and drive lines should be routed away from noisy traces
or components.
For very low input to output voltage differentials, the
input to output/load path should be as wide and short
as possible. Where greater headroom is available, wide
traces may suffice.
SC339 Start-Up Response
Power dissipation within the device is practically
negligible, thus requiring no special consideration during layout. The MOSFET pass devices should be laid out
according to the manufacturer’s guidelines for the power
being dissipated within them.
© 2006 Semtech Corp.
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SC339
PRELIMINARY
POWER MANAGEMENT
Performance Characteristics
Supply Current vs. Supply Voltage
Adjust Voltage vs. Output Current
VCC = 4.5V to 5.5V, IOUT = 2.5A, VIN = 1.5V, VEN = 5V
IOUT = 0A to 3A, VIN = 1.5V, VCC = 5.0V, VEN = 5V
160.0E-6
0.5060
155.0E-6
0.5040
150.0E-6
VADJ (V)
I CC (A)
0.5020
145.0E-6
140.0E-6
0.5000
135.0E-6
0.4980
130.0E-6
0.4960
125.0E-6
4.500
4.600
4.700
4.800
4.900
5.000
5.100
5.200
5.300
5.400
0.4940
0.000
5.500
VCC (V)
0.500
1.000
1.500
2.000
2.500
3.000
IOUT (A)
Supply Current
Adjust Voltage
+1%
-1%
Figure 1: Supply Current v/s Supply Voltage
Figure 2: Adjust Voltage v/s Output Current (1% accurate)
Figure 3: Soft Start waveform shows the PWRGD delay
Figure 4: Input UVLO Test (Rising)
Figure 5: Input UVLO Test (Falling)
© 2006 Semtech Corp.
Figure 6: Enable threshold detect (Rising)
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SC339
POWER MANAGEMENT
Performance Characteristics
Figure 8: Transient load rising edge
Figure 7: Enable threshold detect (Falling)
Figure 9: Transient load falling edge
© 2006 Semtech Corp.
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SC339
PRELIMINARY
POWER MANAGEMENT
Outline Drawing - SOT-23 6
DIMENSIONS
INCHES
MILLIMETERS
DIM
MIN NOM MAX MIN NOM MAX
A
e1
2X E/2
A
A1
A2
b
c
D
E1
E
e
e1
L
L1
N
01
aaa
bbb
ccc
D
N
EI
1
E
2
ccc C
2X N/2 TIPS
e
B
D
aaa C
A2
SEATING
PLANE
bxN
bbb
1.45
0.90
0.00
0.15
.90 1.15 1.30
0.25
0.50
0.22
0.08
2.80 2.90 3.00
1.50 1.60 1.75
2.80 BSC
0.95 BSC
1.90 BSC
0.30 0.45 0.60
(0.60)
6
0°
10°
0.10
0.20
0.20
A
H
A1
C
.057
.035
.006
.000
.035 .045 .051
.020
.010
.009
.003
.110 .114 .118
.060 .063 .069
.110 BSC
.037 BSC
.075 BSC
.012 .018 .024
(.024)
6
10°
0°
.004
.008
.008
C A-B D
H
c
GAGE
PLANE
0.25
L
01
(L1)
SEE DETAIL
A
DETAIL
A
SIDE VIEW
NOTES:
© 2006 Semtech Corp.
1.
CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES).
2.
DATUMS -A- AND -B- TO BE DETERMINED AT DATUM PLANE -H-
3.
DIMENSIONS "E1" AND "D" DO NOT INCLUDE MOLD FLASH, PROTRUSIONS
OR GATE BURRS.
14
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SC339
POWER MANAGEMENT
Land Pattern - SOT-23 6
X
DIM
(C)
G
Z
Y
P
DIMENSIONS
INCHES
MILLIMETERS
C
G
P
X
Y
Z
(.098)
.055
.037
.024
.043
.141
(2.50)
1.40
0.95
0.60
1.10
3.60
NOTES:
1.
THIS LAND PATTERN IS FOR REFERENCE PURPOSES ONLY.
CONSULT YOUR MANUFACTURING GROUP TO ENSURE YOUR
COMPANY'S MANUFACTURING GUIDELINES ARE MET.
Contact Information
Semtech Corporation
Power Management Products Division
200 Flynn Road, Camarillo, CA 93012
Phone: (805) 498-2111 Fax: (805) 498-3804
www.semtech.com
© 2006 Semtech Corp.
15
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