ON FL3100T Low-side gate driver with led pwm dimming control Datasheet

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FL3100T
Low-Side Gate Driver with LED PWM Dimming Control
for Smart LED Lighting
Features
Description

Non-inverting Input Logic with DIM Control Input for
PWM Dimming Down to 0.1% for Hybrid Dimming





4.5 to 18 V Operating Range
The FL3100T 2 A gate driver is designed to drive an Nchannel enhancement-mode MOSFET in low-side
switching applications by providing high peak current
pulses during the short switching intervals. The
FL3100T has two inputs that can be configured to
operate in non-inverting (IN) mode with a DIM pin for
PWM dimming control of the LED Driver. High accuracy
PWM dimming control required in smart LED drivers is
possible by adjusting the duty ratio of the DIM input. If
one or both inputs are left unconnected, internal
resistors bias the inputs such that the output is pulled
LOW to hold the power MOSFET off.




TTL Inputs Independent of Supply Voltage
2.5 A Sink / 1.8 A Source at VOUT = 6 V
Internal Resistors Turn Driver Off If No Inputs
13 ns Typical Rise Time and 9 ns Typical Fall-Time
with 1 nF Load
MillerDrive™ Technology
Typical Propagation Delay Time Under 20 ns with
Input Falling or Rising
6-Lead, 2 x 2 mm MLP or 5-Pin, SOT23 Packages
Rated from -40°C to 125°C Ambient
Applications


Smart LED Drivers with Accurate PWM Dimming
General LED Lighting
The driver is available with fixed TTL input thresholds.
Internal circuitry provides an under-voltage lockout
function by holding the output LOW until the supply
voltage is within operating range. The FL3100T delivers
fast MOSFET switching performance, which helps
maximize efficiency in high-frequency LED driver
designs.
The FL3100T is available in a 5-pin, SOT23 or a
2 x 2 mm, 6-lead, Molded Leadless Package (MLP) for
the smallest size with excellent thermal performance.
Typical Application Circuit
ILED
FL3100T
IN
MCU
VDD
OUT
DIM
Figure 1. LED PWM Dimming Application Circuit for Smart LED Lighting
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
www.fairchildsemi.com
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
August 2015
Part Number
Package
Packing Method
Quantity / Reel
FL3100TMPX
6-Lead, 2 x 2 mm MLP
Tape & Reel
3000
FL3100TSX
5-Pin, SOT23
Tape & Reel
3000
Block Diagrams
1
VDD
5
OUT
2
GND
UVLO
100k
VDD_OK
IN 3
100k
100k
DIM 4
Figure 2.
Simplified Block Diagram (SOT23 Pin-out)
3
VDD
4
OUT
5
PGND
UVLO
100k
VDD_OK
IN 1
100k
100k
DIM 6
AGND 2
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Ordering Information
0.4
Figure 3.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
Simplified Block Diagram (MLP Pin-out)
www.fairchildsemi.com
2
VDD 1
IN 1
6
DIM
AGND 2
5
PGND
VDD 3
4
OUT
Figure 4.
5
OUT
4
DIM
GND 2
IN 3
6-Lead MLP (Top View)
Figure 5.
SOT23-5 (Top View)
Pin Definitions
SOT23 MLP
Pin # Pin #
1
Name
3
VDD
2
AGND
2
GND
Pin Description
Supply Voltage. Provides power to the IC.
Analog ground for input signals (MLP only). Connect to PGND underneath the IC.
Ground (SOT-23 only). Common ground reference for input and output circuits.
3
1
IN
Input. Non-inverting logic. If IN is not used, connect to VDD to enable regular operation
of the output.
4
6
DIM
Dimming Input. Used for PWM dimming. Inverting logic. If dimming is not used, connect
to AGND or PGND to enable regular operation of the output.
5
4
OUT
Gate Drive Output: Held low unless required inputs are present and VDD is above UVLO
threshold.
Pad
P1
5
PGND
Thermal Pad (MLP only). Exposed metal on the bottom of the package, which is
electrically connected to pin 5.
Power Ground (MLP only). For output drive circuit; separates switching noise from
inputs.
Output Logic
IN
DIM
OUT
0
(1)
0
0
0
(1)
(1)
0
1
0
1
1
(1)
0
1
1
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Functional Pin Configurations
Note:
1. Default input signal if no external connection is made.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
www.fairchildsemi.com
3
JL
Package
(3)
JT
(4)
JA
(5)
Unit
6-Lead, 2 x 2 mm Molded Leadless Package (MLP)
2.7
133.0
58.0
°C/W
SOT23-5
56
99
157
°C/W
Notes:
2. Estimates derived from thermal simulation; actual values depend on the application.
3. Theta_JL (JL): Thermal resistance between the semiconductor junction and the bottom surface of all the leads
(including any thermal pad) that are typically soldered to a PCB.
4. Theta_JT (JT): Thermal resistance between the semiconductor junction and the top surface of the package,
assuming it is held at a uniform temperature by a top-side heatsink.
5. Theta_JA (ΘJA): Thermal resistance between junction and ambient, dependent on the PCB design, heat sinking,
and airflow. The value given is for natural convection with no heatsink using a 2SP2 board, as specified in
JEDEC standards JESD51-2, JESD51-5, and JESD51-7, as appropriate.
Absolute Maximum Ratings
Stresses exceeding the absolute maximum ratings may damage the device. The device may not function or be
operable above the recommended operating conditions and stressing the parts to these levels is not recommended.
In addition, extended exposure to stresses above the recommended operating conditions may affect device reliability.
The absolute maximum ratings are stress ratings only.
Symbol
Parameter
Min.
Max.
Unit
-0.3
20.0
V
VDD
VDD to PGND
VIN
Voltage on IN and DIM to GND, AGND, or PGND
GND - 0.3 VDD + 0.3
V
VOUT
Voltage on OUT to GND, AGND, or PGND
GND - 0.3 VDD + 0.3
V
TL
Lead Soldering Temperature (10 Seconds)
TJ
Junction Temperature
TSTG
Storage Temperature
+260
ºC
-55
+150
ºC
-65
+150
ºC
Recommended Operating Conditions
The Recommended Operating Conditions table defines the conditions for actual device operation. Recommended
operating conditions are specified to ensure optimal performance to the datasheet specifications. Fairchild does not
recommend exceeding them or designing to Absolute Maximum Ratings.
Symbol
Parameter
Min.
Max.
Unit
VDD
Supply Voltage Range
4.5
18.0
V
VIN
Input Voltage IN, DIM
0
VDD
V
TA
Operating Ambient Temperature
-40
+125
ºC
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Thermal Characteristics(2)
www.fairchildsemi.com
4
Unless otherwise noted, VDD = 12 V, TJ = -40°C to +125°C. Currents are defined as positive into the device and
negative out of the device.
Symbol
Parameter
Conditions
Min.
Typ.
Max.
Unit
18.0
V
0.50
0.80
mA
Supply
VDD
Operating Range
4.5
IDD
Supply Current Inputs/
EN Not Connected
VON
Turn-On Voltage
3.5
3.9
4.3
V
VOFF
Turn-Off Voltage
3.3
3.7
4.1
V
VINL_T
IN, DIM Logic LOW Voltage, Maximum
0.8
VINH_T
IN, DIM Logic HIGH Voltage, Minimum
Inputs
IIN
V
2.0
V
Non-inverting Input
IN from 0 to VDD
-1
175
µA
IDIMim
DIM Input
IN from 0 to VDD
-175
1
µA
VHYS
IN, DIM Logic Hysteresis Voltage
0.8
V
0.2
0.4
Output
ISINK
OUT Current, Mid-Voltage, Sinking
(6)
ISOURCE
OUT Current, Mid-Voltage, Sourcing
IPK_SINK
OUT Current, Peak, Sinking
(6)
IPK_SOURCE OUT Current, Peak, Sourcing
tRISE
tFALL
tD1, tD2
IRVS
(6)
(6)
(7)
Output Rise Time
Output Fall Time
(7)
Output Prop. Delay, TTL Inputs
2.5
A
OUT at VDD/2,
CLOAD = 0.1 µF, f = 1 kHz
-1.8
A
CLOAD = 0.1 µF, f = 1 kHz
3
A
CLOAD = 0.1 µF, f = 1 kHz
-3
A
CLOAD = 1000 pF
13
20
ns
CLOAD = 1000 pF
9
14
ns
16
30
ns
0 – 5 VIN; 1 V/ns Slew Rate
(7)
Output Reverse Current Withstand
OUT at VDD/2,
CLOAD = 0.1 µF, f = 1 kHz
(6)
500
Notes:
6. Not tested in production.
7. See Timing Diagrams of Figure 6 and Figure 7.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
9
mA
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Electrical Characteristics
www.fairchildsemi.com
5
90%
90%
Output
Output
10%
Input
10%
VINH
PWM
VINL
tD1
tD2
tRISE
Figure 6.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
VINH
VINL
tD1
tD2
t FALL
tFALL
IN Pin
Figure 7.
DIM Pin
t RISE
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Timing Diagrams
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6
Typical characteristics are provided at 25°C and VDD=12 V unless otherwise noted.
Figure 8. IDD (Static) vs. Supply Voltage
Figure 9. IDD (No-Load) vs. Frequency
1 nF Load
Figure 10. IDD (1 nF Load) vs. Frequency
Figure 11. IDD (Static) vs. Temperature
Figure 12. Input Thresholds vs. Supply Voltage
Figure 13. TTL Input Thresholds vs. Temperature
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Typical Performance Characteristics
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7
Typical characteristics are provided at 25°C and VDD=12 V unless otherwise noted.
Figure 14. UVLO Thresholds vs. Temperature
Figure 15. UVLO Hysteresis vs. Temperature
Non-Inverting Input
Figure 16. Propagation Delay vs. Supply Voltage
Figure 17. Propagation Delay vs. Temperature
Inverting Input
Figure 18. Propagation Delay vs. Temperature
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Typical Performance Characteristics
Figure 19. Fall Time vs. Supply Voltage
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8
Typical characteristics are provided at 25°C and VDD=12 V unless otherwise noted.
Figure 20. Rise Time vs. Supply Voltage
Figure 21. Rise and Fall Time vs. Temperature
Figure 22. Rise / Fall Waveforms with 1 nF Load
Figure 23. Rise / Fall Waveforms with 10 nF Load
Figure 24. Quasi-Static Source Current with VDD=12 V
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Typical Performance Characteristics
Figure 25. Quasi-Static Sink Current with VDD=12 V
www.fairchildsemi.com
9
Typical characteristics are provided at 25°C and VDD=12 V unless otherwise noted.
Figure 26. Quasi-Static Source Current with VDD=8 V
Figure 27. Quasi-Static Sink Current with VDD=8 V
VDD
470µF
Al. El.
4.7µF
ceramic
Current Probe
LECROY AP015
IOUT
IN
1kHz
1µF
ceramic
VOUT
CLOAD
0.1µF
Figure 28. Quasi-Static IOUT / VOUT Test Circuit
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Typical Performance Characteristics
www.fairchildsemi.com
10
PWM Dimming
0%
IN
t
OUT
In the typical application circuit, Figure 1 and repeated
here Figure 29, IN is connected to the PWMamplitude
signal coming out of the MCU to control the amplitude of
the overall LED current. This PWMamplitude signal from
the MCU is the same PWM signal based on the
switching frequency of the power stage and error signal
in a closed loop LED driver stage.
t
ILED
Figure 29.
Figure 30.
LED Current with PWM Dimming
Input Thresholds
In the FL3100T, the input thresholds meet industrystandard TTL logic thresholds, independent of the VDD
voltage, and there is a hysteresis voltage of
approximately 0.4 V. These levels permit the inputs to
be driven from a range of input logic signal levels for
which a voltage over 2 V is considered logic HIGH. The
driving signal for the TTL inputs should have fast rising
and falling edges with a slew rate of 6 V/µs or faster, so
the rise time from 0 to 3.3 V should be 550 ns or less.
With reduced slew rate, circuit noise could cause the
driver input voltage to exceed the hysteresis voltage and
retrigger the driver input, causing erratic operation.
Static Supply Current
VDD
In the IDD (static) typical performance graphs (Figure 8,
and Figure 11), the curve is produced with all inputs
floating (OUT is LOW) and indicates the lowest static IDD
current for the tested configuration. For other states,
additional current flows through the 100 k resistors on
the inputs and outputs shown in the block diagrams (see
Figure 2 - Figure 3). In these cases, the actual static IDD
current is the value obtained from the curves plus this
additional current.
OUT
DIM
LED PWM Dimming Application
Under-Voltage Lockout (UVLO)
During amplitude dimming (PWMamplitude), DIM stays low
and there is no PWMlight dimming. When PWMlight
dimming becomes active, e.g. below 20% of amplitude
(PWMamplitude) dimming, then amplitude dimming is held
constant and PWMlight dimming is used to reduce the
light output down to ~0.1% accurately. Figure 30 shows
a possible implementation for mixed mode dimming.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
10%
t
ILED
MCU
100%
50%
DIM is connected to a different PWM signal, also from
the MCU, but is usually a lower frequency signal to
command the PWMlight dimming on the LED current, i.e.
~1 kHz and can be commanded from a wired or wireless
interface such as DALI or ZigBee. Therefore, mixed
mode dimming using both amplitude and PWM dimming
on the LED current is possible.
IN
90%
t
There are two factors to consider, PWMamplitude controls
the LED light output by reducing the forward current in
the LED and PWMlight controls the on time of forward
current in the LED.
FL3100T
50%
DIM
Duty
(%)
FL3100T is used for pulse-width modulation of the LED
current to control the amount of light produced by the
LED in MCU-driven hybrid dimming applications.
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Applications Information
The FL3100T startup logic is optimized to drive ground
referenced N-channel MOSFETs with an Under-Voltage
Lockout (UVLO) function to ensure that the IC starts up
in an orderly fashion. When VDD is rising, yet below the
3.9 V operational level, this circuit holds the output
LOW, regardless of the status of the input pins. After the
part is active, the supply voltage must drop 0.2 V before
the part shuts down. This hysteresis helps prevent
chatter when low VDD supply voltages have noise from
the power switching. This configuration is not suitable
for driving high-side P-channel MOSFETs because the
low output voltage of the driver would turn the P-channel
MOSFET on with VDD below 3.9 V.
www.fairchildsemi.com
11
Layout and Connection Guidelines
To enable this IC to turn a power device on quickly, a
local, high-frequency, bypass capacitor CBYP with low
ESR and ESL should be connected between the VDD
and GND pins with minimal trace length. This capacitor
is in addition to bulk electrolytic capacitance of 10 µF to
47 µF often found on driver and controller bias circuits.
The FL3100T incorporates fast-reacting input circuits,
short propagation delays, and powerful output stages
capable of delivering current peaks over 2 A to facilitate
voltage transition times from under 10 ns to over 100 ns.
The following layout and connection guidelines are
strongly recommended:
A typical criterion for choosing the value of CBYP is to
keep the ripple voltage on the VDD supply ≤5%. Often
this is achieved with a value ≥ 20 times the equivalent
load capacitance CEQV, defined here as Qgate/VDD.
Ceramic capacitors of 0.1 µF to 1 µF or larger are
common choices, as are dielectrics, such as X5R and
X7R, which have good temperature characteristics and
high pulse current capability.
If circuit noise affects normal operation, the value of
CBYP may be increased to 50-100 times the CEQV, or
CBYP may be split into two capacitors. One should be a
larger value, based on equivalent load capacitance, and
the other a smaller value, such as 1-10 nF, mounted
closest to the VDD and GND pins to carry the higherfrequency components of the current pulses.

Keep high-current output and power ground paths
separate from logic input signals and signal ground
paths. This is especially critical when dealing with
TTL-level logic thresholds.

Keep the driver as close to the load as possible to
minimize the length of high-current traces. This
reduces the series inductance to improve highspeed switching, while reducing the loop area that
can radiate EMI to the driver inputs and other
surrounding circuitry.

The FL3100T is available in two packages with
slightly different pinouts, offering similar
performance. In the 6-pin MLP package, Pin 2 is
internally connected to the input analog ground and
should be connected to power ground, Pin 5,
through a short direct path underneath the IC. In
the 5-pin SOT23, the internal analog and power
ground connections are made through separate,
individual bond wires to Pin 2, which should be
used as the common ground point for power and
control signals.

Many high-speed power circuits can be susceptible
to noise injected from their own output or other
external sources, possibly causing output retriggering. These effects can be especially obvious
if the circuit is tested in breadboard or non-optimal
circuit layouts with long input, enable, or output
leads. For best results, make connections to all pins
as short and direct as possible.
MillerDrive™ Gate Drive Technology
FL3100T drivers incorporate the MillerDrive™
architecture shown in Figure 31 for the output stage, a
combination of bipolar and MOS devices capable of
providing large currents over a wide range of supply
voltage and temperature variations. The bipolar devices
carry the bulk of the current as OUT swings between 1/3
to 2/3 VDD and the MOS devices pull the output to the
high or low rail.
The purpose of the MillerDrive™ architecture is to
speed up switching by providing the highest current
during the Miller plateau region when the gate-drain
capacitance of the MOSFET is being charged or
discharged as part of the turn-on / turn-off process.

The turn-on and turn-off current paths should be
minimized as discussed in the following sections.
Figure 32 shows the pulsed gate drive current path
when the gate driver is supplying gate charge to turn the
MOSFET on. The current is supplied from the local
bypass capacitor, CBYP, and flows through the driver to
the MOSFET gate and to ground. To reach the high
peak currents possible, the resistance and inductance in
the path should be minimized. The localized CBYP acts
to contain the high peak current pulses within this driverMOSFET circuit, preventing them from disturbing the
sensitive analog circuitry in the PWM controller.
The output pin slew rate is determined by VDD voltage
and the load on the output. It is not user adjustable, but
if a slower rise or fall time at the MOSFET gate is
needed, a series resistor can be added.
VDD
Input
stage
VOUT
V DD
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
VDD Bypass Capacitor Guidelines
V DS
C BYP
FL3100T
PWM
Figure 31. MillerDrive™ Output Architecture
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
Figure 32.
Current Path for MOSFET Turn-On
www.fairchildsemi.com
12
VDD
VDD
VDS
Turn-on
Threshold
DIM
CBYP
IN
FL3100T
OUT
PWM
Figure 34.
Figure 33.
Table 1.
Thermal Guidelines
Current Path for MOSFET Turn-Off
Gate drivers used to switch MOSFETs and IGBTs at
high frequencies can dissipate significant amounts of
power. It is important to determine the driver power
dissipation and the resulting junction temperature in the
application to ensure that the part is operating within
acceptable temperature limits.
Truth Table of Logic Operation
The truth table indicates the operational states using the
IN and DIM pins.
IN
DIM
OUT
0
0
0
0
1
0
1
0
1
1
1
0
The total power dissipation in a gate driver is the sum of
two components; PGATE and PDYNAMIC:
PTOTAL = PGATE + PDYNAMIC
If the DIM pin is connected to logic HIGH, a disable
function is realized, and the driver output remains LOW
regardless of the state of the IN pin. Likewise, If the IN
pin is connected to logic LOW, a disable function is
realized, and the driver output remains LOW regardless
of the state of the DIM pin.
Operational Waveforms
At power up, the driver output remains LOW until the
VDD voltage reaches the turn-on threshold. The
magnitude of the OUT pulses rises with VDD until
steady-state VDD is reached. The non-inverting
operation illustrated in Figure 34 shows that the output
remains LOW until the UVLO threshold is reached, and
then the output is in-phase with the input.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
IN Startup Waveforms
(1)
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
Figure 33 shows the current path when the gate driver
turns the MOSFET off. Ideally, the driver shunts the
current directly to the source of the MOSFET in a small
circuit loop. For fast turn-off times, the resistance and
inductance in this path should be minimized.
www.fairchildsemi.com
13
PGATE = QG • VGS • fSW
(2)
Dynamic Pre-drive / Shoot-through Current: A power loss
resulting from internal current consumption under
dynamic operating conditions, including pin pull-up /
pull-down resistors, can be obtained using the IDD (noLoad) vs. Frequency graphs in Typical Performance
Characteristics to determine the current IDYNAMIC drawn
from VDD under actual operating conditions:
PDYNAMIC = IDYNAMIC • VDD
PDYNAMIC = 8 mA • 10 V = 0.080 W
(6)
PTOTAL = 0.24 W
(7)
In a system application, the localized temperature
around the device is a function of the layout and
construction of the PCB along with airflow across the
surfaces. To ensure reliable operation, the maximum
junction temperature of the device must be prevented
from exceeding the maximum rating of 150°C; with 80%
derating, TJ would be limited to 120°C. Rearranging
Equation (4) determines the board temperature required
to maintain the junction temperature below 120°C:
(3)
= PTOTAL • JB + TB
(5)
The 5-pin SOT23 has a junction-to-lead thermal
characterization parameter JB = 51°C/W.
Once the power dissipated in the driver is determined,
the driver junction rise with respect to circuit board can
be evaluated using the following thermal equation,
assuming JB was determined for a similar thermal
design (heat sinking and air flow):
TJ
PGATE = 32 nC • 10 V • 500 kHz = 0.160 W
(4)
where:
TJ
= driver junction temperature
JB = (psi) thermal characterization parameter
relating temperature rise to total power
dissipation
TB = board temperature in location defined in the
Thermal Characteristics table.
TB,MAX = TJ - PTOTAL • JB
(8)
TB,MAX = 120°C – 0.24W • 51°C/W = 108°C
(9)
For comparison purposes, replace the 5-pin SOT23
used in the previous example with the 6-pin MLP
package with JB = 2.8°C/W. The 6-pin MLP package
can operate at a PCB temperature of 119°C, while
maintaining the junction temperature below 120°C. This
illustrates that the physically smaller MLP package with
thermal pad offers a more conductive path to remove
the heat from the driver. Consider the tradeoffs between
reducing overall circuit size with junction temperature
reduction for increased reliability.
Typical Application Diagram
Boost
Isolated DC to DC
FL3100T — Low-Side Gate Driver with PWM Dimming Control for Smart LED Lighting
In a typical MOSFET gate drive application, the
FDS2672 would be a potential MOSFET selection. The
typical gate charge would be 32 nC with VGS = VDD =
10 V. Using a TTL input driver at a switching frequency
of 500 kHz, the total power dissipation can be calculated
as:
Gate Driving Loss: The most significant power loss
results from supplying gate current (charge per unit
time) to switch the load MOSFET on and off at the
switching frequency. The power dissipation that results
from driving a MOSFET at a specified gate-source
voltage, VGS, with gate charge, QG, at switching
frequency, fSW, is determined by:
ILED
FL3100T
PWM
Controllers
AC Input
IN
VDD
OUT
DIM
MCU
(DC-DC
Control)
Communication
Chipset
Figure 35.
© 2015 Fairchild Semiconductor Corporation
FL3100T • Rev.1.0
Smart LED Driver using the MCU and FL3100T in the Buck DC-DC Stage
www.fairchildsemi.com
14
2.0
0.05 C
A
1.72
1.68
B
2X
6
4
0.15
2.0
1.21
2.25
0.90
0.52(6X)
0.05 C
PIN#1 IDENT
TOP VIEW
1
2X
3
0.65
0.42(6X)
RECOMMENDED
LAND PATTERN
0.10 C
NOTES:
0.08 C
SIDE VIEW
C
A. PACKAGE DOES NOT FULLY CONFORM
TO JEDEC MO-229 REGISTRATION
SEATING
PLANE
B. DIMENSIONS ARE IN MILLIMETERS.
C. DIMENSIONS AND TOLERANCES PER
ASME Y14.5M, 2009.
D. LAND PATTERN RECOMMENDATION IS
EXISTING INDUSTRY LAND PATTERN.
(0.70)
(0.20)4X
PIN #1 IDENT
1
E. DRAWING FILENAME: MKT-MLP06Krev5.
3
(0.40)
(6X)
(0.60)
6
4
(6X)
0.65
1.30
BOTTOM VIEW
0.10
0.05
C A B
C
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