SEMTECH SC1405DITSTRT

SC1405D
High Speed Synchronous Power
MOSFET Smart Driver
POWER MANAGEMENT
Description
Features
The SC1405D is a Dual-MOSFET Driver with an internal
Overlap Protection Circuit to prevent shoot-through. Each
driver is capable of driving a 3000pF load in 15ns rise/
fall time and has ULTRA-LOW propagation delay from input transition to the gate of the power FETs. Adaptive
Overlap Protection circuit ensures that the synchronous
FET does not turn on until the top FET source has reached
a voltage low enough to prevent shoot-through. The delay between the bottom gate going low to the top gate
transitioning high is externally programmable via a capacitor to minimize dead time. The bottom FET may be
disabled at light loads by keeping S_MOD low to trigger
asynchronous operation, thus saving the bottom FET’s
gate drive current and inductor ripple current.
‹ Fast rise and fall times (15ns withPRELIMINARY
3000pf load)
‹ 14ns max. Propagation delay (BG going with low)
‹ Adaptive and programmable shoot-through
protection
‹ Adaptive overvoltage protection
‹ Wide input voltage range (4.5V - 25V)
‹ Programmable delay between FETs
‹ Power saving asynchronous mode control
‹ Output overvoltage protection/overtemp shutdown
‹ Under-Voltage lock-out and power ready signal
‹ Less than 10µA stand-by current (EN=low)
‹ Power ready output signal
‹ High frequency (to 1.2MHz) operation allows use of
small inductors and low cost caps in place of
electrolytics
‹ TSSOP-14 package
An internal voltage reference allows threshold adjustment
for an Output Over-Voltage protection circuitry, independent of the PWM controller. The device provides overvoltage protection independent of the PWM feedback
loop with a unique “adaptive OVP” comparator which rejects noise but responds quickly to a true OVP situation.
Applications
‹ High Density/Fast transient microprocessor power
supplies
‹ Motor Drives/Class-D amps
‹ High efficiency portable computers
Under-Voltage-Lock-Out circuit is included to guarantee
that both driver outputs are off when Vcc is less than or
equal to 4.4V (typ) at supply ramp up (4.35V at supply
ramp down). A CMOS output provides status indication
of the 5V supply. A low enable input places the IC in standby mode, reducing supply current to less than 10µA.
Typical Application Circuit
Revision: June 8, 2005
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SC1405D
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.
Parameter
Symbol
Minimum
Maximum
Units
VCCMAX
-0.3
7
V
BST to PGND
VMAXBST-PGND
-0.3
30
V
BST to DRN
VMAXBST-DRN
-0.3
8
V
DRN to PGND
VMAXDRN-PGN
DC
-2
25
V
VMAXPULSE
tPULSE < 100nS
-5
25
V
-0.3
10
V
-0.3
VCC + 0.3
V
-1
+1
V
0.66
2.56
W
VCC Supply Voltage
DRN to PGND Pulse
OVP_S to PGND
Conditions
VMAXOVP S-PGND
EN, CO, DSPS, MODE, PRDY,
DELAY to AGND
AGND to PGND
Tamb = 25°C, TJ = 125°C
Tcase = 25°C, TJ = 125°C
Continuous Power Dissipation
Pd
Thermal Impedance Junction to Case
θJ C
40
°C/W
Thermal Impedance Junction to
Ambient
θJ A
150
°C/W
Junction Temperature Range
TJ
-40
+125
°C
Storage Temperature Range
TSTG
-65
+150
°C
Lead Temperature (Soldering) 10 Sec.
TLEAD
300
°C
NOTE:
(1) Specification refers to application circuit.
Electrical Characteristics - DC Operating Specifications
Unless otherwise specified: -40 < TJ < 125°C; VCC = 6V; 4V < VBST < 26V
Parameter
Symbol
Conditions
Min
Typ
Max
Units
4.6
5
6.0
V
10
µA
Pow er Supply
Supply Voltage
Quiescent Current
V CC
Iq_stby
E N = 0V
Iq_op
VCC = 5V, CO = 0V
High Level Output Voltage
VOH
VCC = 4.7V, lload = 10mA
Low Level Output Voltage
VOL
VCC < UVLO threshold,
lload = 10µA
IO_SINK
VPRDY = 0.4V
Quiescent Current, operating
1
mA
4.55
V
PR D Y
Sink Current
 2005 Semtech Corp.
2
4.5
0.1
5
10
0.2
V
mA
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SC1405D
POWER MANAGEMENT
Electrical Characteristics - DC Operating Specifications
Parameter
Symbol
Conditions
Min
High Level Output Voltage
VOH
VCC = 4.6V, Cload = 100pF
4.15
Low Level Output Voltage
VOL
VCC = 4.6V, Cload = 100pF
Typ
Max
Units
D S P S _D R
V
0.05
V
4.6
V
Under Voltage Lockout
Start Threshold
Hysteresis
4.2
Vhys
Logic Active Threshold
4.4
0.05
EN is low
V
1.5
V
1.28
V
Overvoltage Protection
Trip Threshold
Hysteresis
VTRIP
1.17
1.225
0.8
VhysOVP
V
Trip Delay, 50mV Overdrive
TJ = 0 to 125oC
300
470
800
ns
Trip Delay, 100mV Overdrive
TJ = 0 to 125oC
125
225
400
ns
S_MOD
High Level Input Voltage
VIH
Low Level Input Voltage
VIL
2.0
V
0.8
V
Enable
High Level Input Voltage
VIH
Low Level Input Voltage
VIL
2.0
V
0.8
V
CO
High Level Input Voltage
VIH
Low Level Input Voltage
VIL
2.0
V
0.8
V
Thermal Shutdow n
Over Temperature Trip Point
TOTP
165
o
C
Hysteresis
THYST
10
o
C
IPKH
3
A
1
Ω
High-Side Driver
Peak Output Current
Output Resistance
RsrcTG
RsinkTG
duty cycle < 2%, tpw < 100µs,
TJ = 125°C, VBST - VDRN = 4.5V,
VTG = 4.0V (src)+VDRN
or VTG = 0.5V (sink)+VDRN
.7
Low -Side Drive
Peak Output Current
Output Resistance
IPKL
RsrcBG
RsinkBG
 2005 Semtech Corp.
duty cycle < 2%, tpw < 100µs,
TJ = 125°C,
VV S = 4.6V,
VBG = 4V (src)
or VLOWDR = 0.5V (sink)
3
3
A
1.2
Ω
1.0
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SC1405D
POWER MANAGEMENT
Electrical Characteristics - AC Operating Specifications
Parameter
Symbol
Conditions
rise time
trTG1
fall time
Min
Typ
Max
Units
CI = 3nF, VBST - VDRN = 4.6V,
14
23
ns
tfTG
CI = 3nF, VBST - VDRN = 4.6V,
12
19
ns
propagation delay time,
TG going high
tpdhTG
CI = 3nF, VBST - VDRN = 4.6V,
C-delay=0
20
32
ns
propagation delay time,
TG going low
tpdlTG
CI = 3nF, VBST - VDRN = 4.6V,
15
24
ns
High Side Driver
Low -Side Driver
rise time
trBG
CI = 3nF, V
V S
= 4.6V,
15
24
ns
fall time
trBG
CI = 3nF, V
V S
= 4.6V,
13
21
ns
propagation delay time,
BG going high
tpdhBGHI
CI = 3nF, VBST - VDRN = 4.6V,
C-delay=0
12
19
ns
propagation delay time,
TG going low
tpdlBG
CI = 3nF, V V S = 4.6V,
DRN <1V
7
12
ns
V_5 ramping up
tpdhUVLO
EN is High
10
µs
V_5 ramping down
tpdhUVLO
EN is High
10
µs
EN is transitioning from low to
high
tpdhPRDY
V_5 >UVLO threshold, Delay
measured from EN > 2.0V to
PRDY > 3.5V
10
µs
EN is transitioning fro high to low
tpdhUVLO
V_5 >UVLO threshold, Delay
measured from EN < 0.8V to
PRDY < 10% of V_5V
500
µs
trDSPS DR.
CI = 100 pf, V_5 = 4.6V
20
ns
propagation delay, DSPS_DR
going high
tpdhDSPS DR
S_MOD goes high and BG
goes high or S_MOD goes low
10
ns
propagation delay, DSPS_DR
goes low
tpdlDSPS DR
S_MOD goes high and BG
goes low
10
ns
Under-Voltage Lockout
PR D Y
D S P S _D R
rise/fall time
NOTE:
(1) This device is ESD sensitive. Use of standard ESD handling precautions is required.
 2005 Semtech Corp.
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SC1405D
POWER MANAGEMENT
Application Circuit - TSSOP-14
INPUT POWER
+
+
P_READY
>>
PWM IN
(20KHz-1MHz)
47pF
7
2
4
6
1
5
<<
DSPS_DR
MTB75N03
75A,30V
1N5819
.1uF
8
3
<<
+
D1
+5V
10uF,6.3V
+
Vcc
GND
BST
TG
PRDY
EN
DRN
CO
DELAY _C
BG
OVP_S
DSPS_DR
S_MOD PGND
.22uF
14
13
2.2
12
+
+
+
MTB75N03
75A,30V
9
11
10
2.2
SC1405D
Ov er-Voltage Sense
<<< Output Feedback to PWM
Controller
Timing Diagram
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SC1405D
POWER MANAGEMENT
Pin Configuration
Ordering Information
Top View
Device
P ackag e
Temp Range (TJ)
SC1405DITSTRT
TSSOP-14
-40° to 125°C
Notes:
(1) Only available in tape and reel packaging. A reel
contains 2500 devices.
(2) Lead free product. This product is fully WEEE and
RoHS compliant.
(14-Pin TSSOP)
Pin Descriptions
Pin #
Pin Name
Pin Function
1
OVP_S
2
EN
3
GND
4
CO
5
S_MOD
6
DELAY_C
The capacitance connected between this pin and GND sets the additional propagation
delay for BG going low to TG going high. Total propagation delay =20ns + 1ns/pF. If no
capacitor is connected, the propragation delay = 20ns.
7
PRDY
This pin indicates the status of VCC. When VCC is less than the UVLO threshold, this
output is driven low. When VCC is greater than or equals to the UVLO threshold this
output goes high.
8
VC C
Input supply of 5 - 8V. A .22-1µF ceramic capacitor should be connected from VCC to
PGND very close to the chip.
9
BG
10
PGND
11
D S P S _D R
Dynamic Set Point Switch Drive. TTL level output signal. When S-MOD is high, this pin
follows the BG driver pin voltage.
12
DRN
This pin connects to the junction of the switching and synchronous MOSFET's. This pin
can be subjected to a -2V minimum relative to PGND without affecting operation.
13
TG
14
BST
Overvoltage protection sense. External scaling resistors required to set protection
threshold.
When high, this pin enables the internal circuitry of the device. When low, TG, BG, and
PRDY are forced low and the supply current (5V) is less than 10µA.
Logic GND.
TTL-level input signal to the MOSFET drivers.
When low, this signal forces BG to be low, triggering asynchronous operation. When
high, BG is not a function of this signal.
Output drive for the synchrounous (bottom) MOSFET.
Power ground. Connect to the synchronous FET source pin (power ground).
Output gate drive for the switching (high-side) MOSFET.
Bootstrap pin. A capacitor is connected between BST and DRN pins to develop the
floating bootstrap voltage for the high-side MOSFET. The capacitor value is typically
between 0.1µF and 1µF (ceramic).
NOTE:
(1) All logic level inputs and outputs are open collector TTL compatible.
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SC1405D
POWER MANAGEMENT
Block Diagram
Applications Information
SC1405D is designed to drive Low Rds_On power FETs
with ultra-low rise/fall times and propagation delays. As
the switching frequency of PWM controllers is increased
to reduce power supply volume and cost, fast rise and
fall times are necessary to minimize switching losses (TOP
FET) and reduce Dead-time (BOTTOM FET) losses. While
Low Rds_On FETs present a power saving in I2R losses,
the FET’s die area is larger and thus the effective input
capacitance of the FET is increased. Often a 50% decrease in Rds_On more than doubles the effective input
gate charge, which must be supplied by the driver. The
Rds_On power savings can be offset by the switching
and dead-time losses with a suboptimum driver. While
discrete solution can achieve reasonable drive capability, implementing shoot-through, programmable delay and
other housekeeping functions necessary for safe operation can become cumbersome and costly. The SC1405
family of parts presents a total solution for the highspeed, high power density applications. Wide input supply range of 4.5V-25V allows use in battery powered applications, new high voltage, distributed power servers
as well as Class-D amplifiers.
by holding the bottom FET off until the voltage at the
phase node (intersection of top FET source, the output
inductor and the bottom FET’s drain) has dropped below
1V. This assures that the top FET has turned off and
that a direct current path does not exist between the
input supply and ground, a condition which both the top
and bottom FETs are on momentarily. The top FET is
also prevented from turning on until the bottom FET is
off. This time is internally set to 20ns (typical) and may
be increased by adding a capacitor from the C-Delay pin
to GND. The delay is approximately 1ns/pF in addition
to the internal 20ns delay. The external capacitor may
be needed if multiple High input capacitance FETs are
used in parallel and the fall time is substantially greater
than 20ns.
Theory of Operation
As with any high speed , high current circuit, proper layout is critical in achieving optimum performance of the
SC1405D. The Evaluation board schematic on page 12
shows a dual phase synchronous design with all surface
mountable components.
It must be noted that increasing the dead-time by high
values of C-Delay capacitor will reduce efficiency since
the parallel Schottky or the bottom FET’s body diode will
have to conduct during dead-time.
Layout Guidelines
The control input (CO) to the SC1405D is typically supplied by a PWM controller that regulates the power supply output. (See Application Evaluation Schematic on page
12). The timing diagram demonstrates the sequence of
events by which the top and bottom drive signals are
applied. The shoot-through protection is implemented
 2005 Semtech Corp.
While components connecting to C-Delay, OVP_S, EN,SMOD, DSPS_DR and PRDY are relatively noncritical, tight
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SC1405D
POWER MANAGEMENT
Applications Information
the Miller feedback and thus reduces Vspike. Also FETs
with higher Turn-on threshold voltages will conduct at a
higher voltage and will not turn on during the spike. The
FET shown in the schematic has a 2 volt threshold and
will require approximately 5 volts Vgs to be conducting,
thus reducing the possibility of shoot-through. A zero
ohm bottom FET gate resistor will obviously help keeping
the gate voltage low.
placement and short, wide traces must be used in layout
of The Drives, DRN, and especially PGND pin. The top
gate driver supply voltage is provided by bootstrapping
the +5V supply and adding it the phase node voltage
(DRN). Since the bootstrap capacitor supplies the charge
to the TOP gate, it must be less than 0.5” away from the
SC1405. Ceramic X7R capacitors are a good choice for
supply bypassing near the chip. The Vcc pin capacitor
must also be less than 0.5” away from the SC1405. The
ground node of this capacitor, the SC1405 PGND pin
and the Source of the bottom FET must be very close to
each other, preferably with common PCB copper land
and multiple vias to the ground plane (if used). The parallel Schottky (if used) must be physically next to the
Bottom FET’s drain and source. Any trace or lead inductance in these connections will drive current way from
the Schottky and allow it to flow through the FET’s body
diode, thus reducing efficiency.
Ultimately, slowing down the top FET by adding gate resistance will reduce di/dt which will in turn make the effective impedance of the capacitors higher, thus allowing the BG driver to hold the bottom gate voltage low.
Ringing on the Phase Node
The top FET source must be close to the bottom FET
drain to prevent ringing and the possibility of the phase
node going negative. This frequency is determined by:
Preventing Inadvertent Bottom FET Turn-on
Fring =
At high input voltages, (12V and greater) a fast turn-on
of the top FET creates a positive going spike on the Bottom FET’s gate through the Miller capacitance, Crss of
the bottom FET. The voltage appearing on the gate due
to this spike is:
Vspike =
Where:
Lst = The effective stray inductance of the top FET added
to trace inductance of the connection between top FET’s
source and the bottom FET’s drain added to the trace
resistance of the bottom FET’s ground connection.
Vin * Crss
Crss + Ciss
Coss=Drain to source capacitance of bottom FET. If there
is a Schottky used, the capacitance of the Schottky is
added to the value.
Where Ciss is the input gate capacitance of the bottom
FET. This is assuming that the impedance of the drive
path is too high compared to the instantaneous impedance of the capacitors. (since dV/dT and thus the effective frequency is very high). If the BG pin of the SC1405D
is very close to the bottom FET, Vspike will be reduced
depending on trace inductance, rate if rise of current,
etc.
Although this ringing does not pose any power losses
due to a fairly high Q, it could cause the phase node to
go too far negative, thus causing improper operation,
double pulsing or at worst driver damage. This ringing is
also an EMI nuisance due to its high resonant frequency.
Adding a capacitor, typically 1000-2000pf, in parallel with
Coss can often eliminate the EMI issue. If double pulsing is caused due to excessive ringing, placing 4.7-10
ohm resistor between the phase node and the DRN pin
of the SC1405 should eliminate the double pulsing.
While not shown in Application Evaluation Board Schematic on page 12, a capacitor may be added from the
gate of the bottom FET to its source, preferably less than
0.5” away. This capacitor will be added to Ciss in the
above equation to reduce the effective spike voltage,
Vspike.
The negative voltage spikes on the phase node adds to
the bootstrap capacitor voltage, thus increasing the voltage between VBST - VDRN. If the phase node negative
spikes are too large, the voltage on the boost capacitor
The selection of the bottom FET must be done with attention paid to the Crss/Ciss ratio. A low ratio reduces
 2005 Semtech Corp.
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2Π L st * Coss
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SC1405D
POWER MANAGEMENT
Applications Information (Cont.)
could exceed device’s absolute maximum rating of 8V.
To eliminate the effect of the ringing on the boost
capacitor voltage, place a 4.7 - 10 Ohm resistor between
boost Schottky diode and Vcc to filter the negative spikes
on DRN Pin. Alternately, a Silicon diode, such as the
commonly available 1N4148 can substitute for the
Schottky diode and eliminate the need for the series resistor.
DSPS DR
This pin produces an output which is a logical duplicate
of the bottom FET’s gate drive, if S-MOD is held High.
OVP_S/OVER TEMP SHUTDOWN
Output over-voltage protection (OVP) may be implemented
on the SC1405D independent of the PWM controller . A
voltage divider from the output is compared with the internal bandgap voltage of 1.2V (typical). Upon exceeding
this voltage, the overvoltage comparator disables the top
FET, while turning on the bottom FET to allow discharge
of the output capacitors excessive voltage through the
output inductor.
Proper layout will guarantee minimum ringing and eliminate the need for external components. Use of SO-8 or
other surface mount FETs will reduce lead inductance
and their parasitic effects.
ASYNCHRONOUS OPERATION
The SC1405D can be configured to operate in Asynchronous mode by pulling S-MOD to logic LOW, thus disabling
the bottom FET drive. This has the effect of saving power
at light loads since the bottom FET’s gate capacitance
does not have to charged at the switching frequency.
There can be a significant savings since the bottom driver
can supply up to 2A pulses to the FET at the switching
frequency. There is an additional efficiency benefit to
operating in asynchronous mode. When operating in synchronous mode, the inductor current can go negative
and flow in reverse direction when the bottom FET is on
and the DC load is less than 1/2 inductor ripple current.
At that point, the inductor core and wire losses, depending on the magnitude of the ripple current, can be quite
significant. Operating in asynchronous mode at light loads
effectively only charges the inductor by as much as
needed to supply the load current, since the inductor
never completely discharges at light loads. DC regulation can be an issue when operating in asynchronous
mode, depending on the type of controller used and minimum load required to maintain regulation. If there are
no Shottkey diodes used in parallel with bottom FET, the
FET’s body diode will need to conduct in asynchronous
mode. The high voltage drop of this diode must be considered when determining the criteria for this mode of
operation.
 2005 Semtech Corp.
The SC1405D has a unique adaptive OVP circuit. Short
noise pulses, less than ~100ns are rejected completely;
longer pulses will trigger OVP if only of sufficient magnitude. A long term transient will trigger OVP with a smaller
magnitude. To assure proper tripping, bypass the resistor from OVP_S pin to GND with a capacitor. The value of
this capacitor must be selected to achieve a time constant equal to one switching period. Leave at least 250mV
headroom on the OVP pin to prevent false OVP events.
The SC1405D will shutdown if its TJ exceeds 165°C.
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SC1405D
POWER MANAGEMENT
Typical Characteristics
Performance diagrams, Application Evaluation Board.
PIN Descriptions
PIN
Descriptions
Timing diagram:
Ch1: CO input
Ch2: TG drive
Ch3: BG non-overlap drive
Ch4: phase node
Iout = 20A (10A/phase)
Refer to Eval. Schematic
(fig.3)
Timing diagram:
Rise/Fall times
Ch1: TG drive
Ch2: BG drive
Cursor: TpdhTG
Iout = 20A (10A/phase)
Refer to Eval. Schematic
(fig.3)
VIN = 12V, VOUT = 1.6V. Top FET = IR7811 FDB7030(BL) Qgd = 23nc
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SC1405D
POWER MANAGEMENT
Typical Characteristics (Cont.)
SC1405D OVP Delay vs. Temperature
600.00
500.00
Delay (nS)
400.00
300.00
200.00
100.00
0.00
-25
-5
15
35
55
75
95
115
135
Temperature (C)
50mV Overdrive
100mV Overdrive
Typical Delay vs. Overdrive (T=25C)
Delay (nS)
10000
1000
100
10
1000
Overdrive (mV)
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VR_ON
CORESW
V_GATE
12
VID0
DPRSLPVR
9
11
8
VID1
DPSLP#
7
VID2
10
6
VID3
GMUXSEL
5
4
VID4
OSB
O SB
R9 69.8k
1
2
3
OSD
O SD
1
R7 21.5k
1
2
HYS
OSDR 2
2
HYS
R5 6.8k O S D R
1
2
R2 51k
1
DPRSLPVR
DPSLP#
EN
SS
CORE
DAC
GND
CO
VCC
CMP
CMPREF
CL
CLREF
PWRGOOD
SC1471
GMUXSEL
VID0
VID1
VID2
VID3
VID4
OSB
OSD
OSDR
HYS
U1
13
14
15
16
17
18
19
20
21
22
23
24
71_ON
SS
CORE
DAC
CO
VCCC
CMP
1
R11
620
1
620
1.24k
1
2
1
10
DAC
R16
1.8nF
C13
2
1
C11 1nF
2
2
R24
CMPREF
CL
CLREF
1
2
R1
1
2
1
1
1nF
C24
100
R17
C10
2
0.1uF
120pF 1
C7
1
2
2
2
2
1
2
NO_POP
C21
1
2
CMP
PRDY
DRN
TG
BST
VCC
BG
PGND
DSPSDR
SC1405D
DELAYC
SMOD
CO
GND
EN
10.0k
R12
1
8
9
10
11
12
13
14
1uF
NOTE: Populate R12, C12, and
R14 for redundant OVP. Ground
Pin 1 if redundant OVP is not
required.
7
6
5
4
3
2
OVPS
U2
470pF
C12
OVPS 1
OH
C O RE
2
DELAYC
R8 787
R6 787
1
BA L
C LO H
+VCORE
1
180pF
1
180pF
C8
C9
2
2
R4 750
R3 750
1
2
BG
TG
BST
1
2
1
2
1uF
C22
1.0u
C14
1
R13
1
R10
10uF
C2
Q1
IRF7811A
2 TG14
2
1
2
10uF
C3
1
2
10uF
C4
1
2
10uF
C5
Q3
D
FDS6674A
4
PHASE
1
Q4
D
2
Q2
R15
D
1
Q5
D
10uF/1206
2
CS+
L-R
1
2
0.002
C33
FDS7764A
4
4
IRF7811A
L1 0.6uH
TG2
D
1
2
CS-
Rout CS+, CS- as a differential pair.
1
2
PHASE
FDS6674A
4
1
1
MBR0530
D1
8
7
6
5
C1
8
7
6
5
3
2
1
+
R14
150uF
C18
6.65k
150uF
C15
MBRS130L
D2
+
10uF
C6
1
2
8
7
6
5
3
2
1
8
7
6
5
3
2
1
1
2
3
2
1
8
7
6
5
3
2
1
1
2
1
2
1
2
2
2
1
+
150uF
C16
+
150uF
C19
GND
+V_IN
+5Vcc
1
2
1
2
12
+
150uF
C17
+
150uF
C20
+VCORE
1
 2005 Semtech Corp.
2
+3_3V
SC1405D
POWER MANAGEMENT
Evaluation Board Schematic
www.semtech.com
SC1405D
POWER MANAGEMENT
Outline Drawing -TSSOP-14
A
DIMENSIONS
INCHES
MILLIMETERS
DIM
MIN NOM MAX MIN NOM MAX
D
A
A1
A2
b
c
D
E1
E
e
L
L1
N
01
aaa
bbb
ccc
2X E/2
E1
E
PIN 1
INDICATOR
ccc C
2X N/2 TIPS
1 2 3
e
B
aaa C
SEATING
PLANE
.047
.006
.002
.042
.031
.007
.012
.007
.003
.193 .197 .201
.169 .173 .177
.252 BSC
.026 BSC
.018 .024 .030
(.039)
14
8°
0°
.004
.004
.008
1.20
0.05
0.15
0.80
1.05
0.19
0.30
0.20
0.09
4.90 5.00 5.10
4.30 4.40 4.50
6.40 BSC
0.65 BSC
0.45 0.60 0.75
(1.0)
14
0°
8°
0.10
0.10
0.20
D
A2 A
A1
C
c
GAGE
PLANE
bxN
bbb
H
C A-B D
0.25
L
(L1)
DETAIL
SIDE VIEW
SEE DETAIL
01
A
A
NOTES:
1.
CONTROLLING DIMENSIONS ARE IN MILLIMETERS (ANGLES IN DEGREES).
2. DATUMS -A- AND -B- TO BE DETERMINED AT DATUM PLANE -H3. DIMENSIONS "E1" AND "D" DO NOT INCLUDE MOLD FLASH, PROTRUSIONS
OR GATE BURRS.
4. REFERENCE JEDEC STD MO-153, VARIATION AB-1.
 2005 Semtech Corp.
13
www.semtech.com
SC1405D
POWER MANAGEMENT
Land Pattern - TSSOP-14
X
DIM
(C)
G
DIMENSIONS
INCHES
MILLIMETERS
C
G
P
X
Y
Z
Z
Y
(.222)
.161
.026
.016
.061
.283
(5.65)
4.10
0.65
0.40
1.55
7.20
P
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
 2005 Semtech Corp.
14
www.semtech.com